Optimizing multiphoton fluorescence microscopy light collection from living tissue by noncontact total emission detection (epiTED).

A benefit of multiphoton fluorescence microscopy is the inherent optical sectioning that occurs during excitation at the diffraction-limited spot. The scanned collection of fluorescence emission is incoherent; that is, no real image needs to be formed on the detector plane. The nearly isotropic emission of fluorescence excited at the focal spot allows for new detection schemes that efficiently funnel all attainable photons to detector(s). We previously showed [Combs, C.A., et al. (2007) Optimization of multiphoton excitation microscopy by total emission detection using a parabolic light reflector. J. Microsc. 228, 330-337] that parabolic mirrors and condensers could be combined to collect the totality of solid angle around the excitation spot for tissue blocks, leading to ∼8-fold signal gain. Using a similar approach, we have developed an in vivo total emission detection (epiTED) instrument modified to make noncontact images from outside of living tissue. Simulations suggest that a ∼4-fold enhancement may be possible (much larger with lower NA objectives than the 0.95 NA used here) with this approach, depending on objective characteristics, imaging depth and the characteristics of the sample being imaged. In our initial prototype, 2-fold improvements were demonstrated in the mouse brain and skeletal muscle as well as the rat kidney, using a variety of fluorophores and no compromise of spatial resolution. These results show this epiTED prototype effectively doubles emission signal in vivo; thus, it will maintain the image signal-to-noise ratio at two times the scan rate or enable full scan rate at approximately 30% reduced laser power (to minimize photo-damage).

Nanosecond dynamics of the single tryptophan reveals multi-state equilibrium unfolding of protein GB1.

Unfolding of the immunoglobulin binding domain B1 of streptococcal protein G (GB1) was induced by guanidine hydrochloride (GdnHCl) and studied by circular dichroism, steady-state, and time-resolved fluorescence spectroscopy. The fluorescence methods employed the single tryptophan residue of GB1 as an intrinsic reporter. While the transitions monitored by circular dichroism and steady-state fluorescence coincided with each other, the transitions followed by dynamic fluorescence were markedly different. Specifically, fluorescence anisotropy data showed that a relaxation spectrum of tryptophan contained a slow motion with relaxation times of 9 ns in the native state and 4 ns in the unfolded state in 6 M GdnHCl. At intermediate GdnHCl concentrations of 3.8-4.2 M, however, the slow relaxation time increased to 18 ns. The fast nanosecond motion had an average time of 0.8 ns and showed no dependence on the formation of native structure. Overall, dynamic fluorescence revealed two preliminary stages in GB1 folding, which are equated with the formation of local structure in the beta(3)-strand hairpin and the initial collapse. Both stages exist without alpha-helix formation, i. e., before the appearance of any ordered secondary structure detectable by circular dichroism. Another stage in GB1 folding might exist at very low ( approximately 1 M) GdnHCl concentrations.

Nanosecond dynamics of tryptophans in different conformational states of apomyoglobin proteins.

Fluorescence anisotropy kinetics were employed to quantify the nanosecond mobility of tryptophan residues in different conformational states (native, molten globule, unfolded) of apomyoglobins. Of particular interest is the similarity between the fluorescence anisotropy decays of tryptophans in the native and molten globule states. We find that, in these compact states, tryptophan residues rotate rapidly within a cone of semiangle 22-25 degrees and a correlation time of 0.5 ns, in addition to rotating together with the whole protein with a correlation time of 7-11 ns. The similar nanosecond dynamics of tryptophan residues in both states suggests that the conformation changes that distinguish the molten globule and native states of apomyoglobins originate from either subtle, slow rearrangements or fast changes distant from these tryptophans.

Visual detection of transport-P in peptidergic neurones.

1. Hypothalamic peptidergic neurones possess an uptake process for amines (transport-P), for which prazosin is a substrate. It is characterized by a paradoxical increase in the accumulation of [3H]-prazosin when the concentration of unlabelled prazosin is increased above 10(-7) M. This increase is due to activation of a proton-dependent, vacuolar-type ATPase-linked pump that is blocked by tricyclic antidepressants. This study utilized a fluorescence method to detect amine uptake in individual cells. 2. Prazosin is fluorescent but most of its emission spectrum is in the ultraviolet range. We therefore used an analogue of prazosin in which the furan ring had been substituted with a fluorescent group, BODIPY FL. This compound's emission maximum is in the green part of the visible spectrum. 3. BODIPY FL prazosin accumulated in immortalised peptidergic neurones and the characteristic emission spectrum of the compound was evident in these cells. Accumulation of BODIPY FL prazosin was saturable and was inhibited by the tricyclic antidepressant desipramine and by unlabelled prazosin. As previously described for prazosin, uptake of BODIPY FL prazosin was blocked by cold temperature and by the organic base chloroquine. Thus, prazosin and BODIPY FL prazosin were accumulated by the same uptake process. 4. BODIPY FL prazosin accumulated in a granular distribution, which is compatible with storage in intracellular vesicles. 5. Hypothalamic cells from foetal rats in primary culture also accumulated BODIPY FL prazosin by a desipramine-sensitive process. Uptake was predominantly in neurones and glial cells did not accumulate the amine. 6. Fluorescent detection provides visual evidence for amine uptake in peptidergic neurones and should enable detailed study of the distribution of this process in the brain.

Zn2+ promotes the self-association of human immunodeficiency virus type-1 integrase in vitro.

It has been recently demonstrated that the Mg(2+)-dependent 3'-processing activity of purified human immunodeficiency virus type-1 (HIV-1) integrase is stimulated by the addition of exogenous Zn2+ [Lee, S. P., & Han, M. K. (1996) Biochemistry 35, 3837-3844]. This activation was hypothesized to result from integrase self-association. In this report, we examine the Zn2+ content of purified HIV-1 integrase by atomic absorption spectroscopy and by application of a thiol modification reagent, p-(hydroxymercuri)benzenesulfonate, with a metallochromic indicator, 4-(2-pyridylazo)resorcinol. We find that the Zn2+ content of HIV-1 integrase varies from 0.1 to 0.92 equiv of Zn2+ per monomer depending on the conditions of protein purification. In vitro activity assays, time-resolved fluorescence emission anisotropy, and gel filtration chromatographic analyses all indicate that EDTA yields an apoprotein which is predominantly monomeric and less active with Mg2+. Further, sedimentation equilibrium studies reveal that reconstitution of the apoprotein with Zn2+ results in a monomer-tetramer-octamer transition. These results suggest that Zn2+ promotes a conformation with enhanced oligomerization and thereby stimulates Mg(2+)-dependent 3'-processing. This may also imply that multimers larger than dimers (tetramers and possibly octamers) are required for in vitro activity of integrase in the presence of Zn2+ and Mg2+. It should be noted, however, that the content of Zn2+ did not significantly affect the 3'-processing and strand transfer reactions with Mn2+ in vitro.

Fluorescence properties of pteridine nucleoside analogs as monomers and incorporated into oligonucleotides.

Eighteen fluorescent pteridine-based nucleoside analogs have been prepared that are suitable for synthesis as phosphormidites and site-specific incorporation into oligonucleotides. Their quantum yields ranged from < or = 0.03 to 0.88. The maximum excitation and emission wavelenghts of seven selected probes with quantum yields > 0.15 ranged from 334 to 358 and 400 to 444 nm, respectively. Fluorescence decay curves of the seven probes were biexponential, and the mean intensity-weighted lifetimes ranged from 0.87 to 6.54 ns. Incorporation of probes 4 and 17 (3-methylisoxanthopterin and 6-methylisoxanthopterin) into oligonucleotides significantly quenched their fluorescence signal, and the degree of quench correlated with the number and proximity of purines in the oligonucleotide. Incorporation also resulted in a shift in absorbance-, emission-, and decay-associated spectra for 6-methylisoxanthopterin. An increase in the complexity of the decay curve and a decrease in the mean lifetime occurred for both probes. Formation of double-stranded oligonucleotides did not substantially increase the degree of quenching but generally increased the complexity of decay curves and decreased the mean lifetimes. Melting temperature, Tm, depression equivalent to that of a single base pair mismatch was observed in 3-methylisoxanthopterin-containing double-stranded oligonucleotides, while the Tm of 6-methylisoxanthopterin-containing double-stranded oligonucleotides were unperturbed, e.g., equivalent to unlabeled double-stranded oligonucleotides. This new class of fluorophore yields promising probes for the study of protein/DNA interactions.

CD44 expression in benign and malignant nevomelanocytic lesions.

CD44 is an integral membrane glycoprotein that is a principal receptor for hyaluronan and plays a role in cell-extracellular matrix interactions. Recent studies of melanomas in mouse models have suggested that increased CD44 expression by these tumors may relate to metastatic potential. Immunohistochemical expression of CD44 (standard [s] and variant [v6]) in benign and malignant nevomelanocytic lesions was assessed in formalin-fixed, paraffin-embedded tissue and was correlated with histological parameters and prognostic factors. Cases included benign nevi (three junctional, four compound, five intradermal, five blue, six Spitz, one deep penetrating), architecturally disordered (dysplastic) nevi (three, and primary (22) and metastatic melanomas (eight). All of the benign lesions showed diffuse and essentially uniform membrane staining of CD44s in nevomelanocytic cells, regardless of lesion size, depth, or extent of dermal involvement. In contrast, semiquantitative analysis (0 to 3+) of the primary melanomas showed heterogeneous and decreased staining of CD44s, which inversely correlated with lesion size (-0.569) and depth of invasion (-0.622 and -0.617 for Breslow's depth and Clark's level, respectively). These results were significant at P < .05. CD44s expression in metastases paralleled that of their respective primaries. None of the benign nevomelanocytic lesions showed CD44v6 staining. In contrast, all of the malignant nevomelanocytic lesions showed cytoplasmic staining of the tumor cells. Pretreatment with chondroitinase did not alter CD44s staining. CD44s expression by immunohistochemical determination is uniform in benign nevomelanocytic lesions. Malignant melanomas show decreased, heterogeneous staining that inversely correlates with increasing size, depth, and level of invasion. CD44 expression may be a prognostic indicator in malignant melanomas. Tumor staining with anti-chondroitin sulfate monoclonal antibodies suggests that CD44s may be expressed as a chondroitin sulfate proteoglycan in primary melanomas.

Cell surface chondroitin sulfate proteoglycans in tumor cell adhesion, motility and invasion.

Tumor cell invasion and metastasis is highly dependent on dynamic changes in the adhesion and migration of transformed and malignant cells. As with normal cell adhesion, the adhesion of tumor cells influences their cytoskeletal organization, activation of signal transduction pathways within the cell, and nuclear events leading to changes in mRNA transcription and protein synthesis. Furthermore, as tumor cells invade the circulation, they adhere to activated endothelial cells at sites within the vasculature during arrest and extravasation. Studies in the area of tumor cell adhesion and migration have demonstrated that the recognition of extracellular matrix ligands, or adhesion promoting ligands expressed on neighboring cells (i.e. counter-receptors), involves complex molecular recognition mechanisms. The complexity arises, in part, from the multiple recognition sites that are present within adhesion promoting ligands. Some of these structures within ECM components act by binding integrins, whereas others bind additional receptors such as cell surface proteoglycans. In this sense, adhesion promoting ligands may be considered as informational arrays, that function to modulate cell phenotype by engaging specific combinations of adhesion receptors on the cell surface. Understanding the mechanism(s) by which these receptor 'cluster' modify cell adhesion, motility and growth may lead to novel therapeutic strategies to control tumor cell invasion and metastasis formation. This review will highlight the role that cell surface chondroitin sulfate proteoglycans may play in modulating tumor cell adhesion, migration and invasion, with an emphasis on the relationship between cell surface chondroitin sulfate proteoglycans and integrins.

CD44-related chondroitin sulfate proteoglycan, a cell surface receptor implicated with tumor cell invasion, mediates endothelial cell migration on fibrinogen and invasion into a fibrin matrix.

Microvascular endothelial cell invasion into the fibrin provisional matrix is an integral component of angiogenesis during wound repair. Cell surface receptors which interact with extracellular matrix proteins participate in cell migration and invasion. Malignant cells use CD44-related chondroitin sulfate proteoglycan (CSPG) as a matrix receptor to mediate migration and invasion. In this study, we examine whether cell surface CSPG can mediate similar events in nonmalignant wound microvascular endothelial cells or whether use of CSPG for migration and invasion is a property largely restricted to malignant cells. After inhibiting CSPG synthesis with p-nitrophenyl beta-d xylopyranoside (beta-d xyloside), wound microvascular endothelial cells were capable of attaching and spreading on the surface of a fibrin gel; however, their ability to invade the fibrin matrix was virtually eliminated. To begin to examine the mechanism by which endothelial cells use CSPG to invade fibrin matrices, cell adhesion and migration on fibrinogen was examined. Endothelial cell adhesion and migration on fibrinogen were inhibited by both beta-d xyloside and after cleavage of chondroitin sulfate from the core protein by chondroitinase ABC. We have determined that wound microvascular endothelial cells express the majority of their proteoglycan as CSPG and that the CSPG core protein is immunologically related to CD44. PCR studies show that these cells express both the "standard" (CD44H) isoform and an isoform containing the variably spliced exon V3. In addition, anti-CD44 antibody blocks endothelial cell migration on fibrinogen. Affinity chromatography studies reveal that partially purified microvascular endothelial cell CSPG binds fibrinogen. These findings suggest that CD44-related CSPG, a molecule implicated in the invasive behavior of tumor cells, is capable of binding fibrinogen/fibrin, thereby mediating endothelial cell migration and invasion into the fibrin provisional matrix during wound repair.

CD44/chondroitin sulfate proteoglycan and alpha 2 beta 1 integrin mediate human melanoma cell migration on type IV collagen and invasion of basement membranes.

Tumor cell invasion of basement membranes (BM) represents one of the critical steps in the metastatic process. Tumor cell recognition of individual BM matrix components may involve individual cell adhesion receptors, such as integrins or cell surface proteoglycans, or may involve a coordinate action of both types of receptors. In this study, we have focused on the identification of a cell surface CD44/chondroitin sulfate proteoglycan (CSPG) and alpha 2 beta 1 integrin on human melanoma cells that are both directly involved in the in vitro invasion of reconstituted BM via a type IV collagen-dependent mechanism. Interfering with cell surface expression of human melanoma CSPG with either p-nitro-phenyl-beta-D-xylopyranoside treatment or anti-CD44 monoclonal antibody (mAb) preincubation (mAb) preincubation inhibits melanoma cell invasion through reconstituted BM. These treatments also strongly inhibit melanoma cell migration on type IV collagen, however, they are ineffective at inhibiting cell adhesion to type IV collagen. Purified melanoma cell surface CD44/CSPG, or purified chondroitin sulfate, bind to type IV collagen affinity columns, consistent with a role for CD44/CSPG-type IV collagen interactions in mediating tumor cell invasion. In contrast, melanoma cell migration on laminin (LM) does not involve CD44/CSPG, nor does CD44/CSPG bind to LM, suggesting that CD44/CSPG-type IV collagen interactions are specific in nature. Additionally, anti-alpha 2 and anti-beta 1 integrin mAbs are capable of blocking melanoma cell invasion of reconstituted BM. Both of these anti-integrin mAbs inhibit melanoma cell adhesion and migration on type IV collagen, whereas only anti-beta 1 mAb inhibits cell adhesion to LM. Collectively, these results indicate that melanoma cell adhesion to type IV collagen is an important consideration in invasion of reconstituted BM in vitro, and suggest that CD44/CSPG and alpha 2 beta 1 integrin may collaborate to promote human melanoma cell adhesion, migration, and invasion in vivo.

Critical amino acids in the transcriptional activation domain of the herpesvirus protein VP16 are solvent-exposed in highly mobile protein segments. An intrinsic fluorescence study.

Eukaryotic transcriptional regulatory proteins typically comprise both a DNA binding domain and a regulatory domain. Although the structures of many DNA binding domains have been elucidated, no detailed structures are yet available for transcriptional activation domains. The activation domain of the herpesvirus protein VP16 has been an important model in mutational and biochemical studies. Here, we characterize the VP16 activation domain using time-resolved and steady-state fluorescence. Unique intrinsic fluorescent probes were obtained by replacing phenylalanine residues with tryptophan at position 442 or 473 of the activation domain of VP16 (residues 413-490, or subdomains thereof), linked to the DNA binding domain of the yeast protein GAL4. Emission spectra and quenching properties of Trp at either position were characteristic of fully exposed Trp. Time-resolved anisotropy decay measurements suggested that both Trp residues were associated with substantial segmental motion. The Trp residues at either position showed nearly identical fluorescence properties in either the full-length activation domain or relevant subdomains, suggesting that the two subdomains are similarly unstructured and have little effect on each other. As this domain may directly interact with several target proteins, it is likely that a significant structural transition accompanies these interactions.

Transcriptional activation domain of the herpesvirus protein VP16 becomes conformationally constrained upon interaction with basal transcription factors.

The transcriptional activation domain of the herpesvirus protein VP16 resides in the carboxyl-terminal 78 amino acids (residues 413-490). Fluorescence analyses of this domain indicated that critical amino acids are solvent-exposed in highly mobile segments. To examine interactions between VP16 and components of the basal transcriptional machinery, we incorporated (at position 442 or 473 of VP16) tryptophan analogs that can be selectively excited in complexes with other Trp-containing proteins. TATA-box binding protein (TBP) (but not transcription factor B (TFIIB)) caused concentration-dependent changes in the steady-state anisotropy of VP16, from which equilibrium binding constants were calculated. Quenching of the fluorescence from either position (442 or 473) was significantly affected by TBP, whereas TFIIB affected quenching only at position 473. 7-aza-Trp residues at either position showed a emission spectral shift in the presence of TBP (but not TFIIB), indicating a change to a more hydrophobic environment. In anisotropy decay experiments, TBP reduced the segmental motion at either position; in contrast, TFIIB induced a slight change only at position 473. Our results support models of TBP as a target protein for transcriptional activators and suggest that ordered structure in the VP16 activation domain is induced upon interaction with target proteins.

A peptide model of basement membrane collagen alpha 1 (IV) 531-543 binds the alpha 3 beta 1 integrin.

Tumor cell adhesion to the triple-helical domain of basement membrane (type IV) collagen occurs at several different regions. Cellular recognition of the sequence spanning alpha 1(IV)531-543 has been proposed to be independent of triple-helical conformation (Miles, A. J., Skubitz, A. P. N., Furcht, L. T., and Fields, G. B. (1994) J. Biol. Chem. 269, 30939-30945). In the present study, integrin interactions with a peptide analog of the alpha 1(IV)-531-543 sequence have been analyzed. Tumor cell adhesion (melanoma, ovarian carcinoma) to the alpha 1(IV)531-543 chemically synthesized peptide was inhibited by a monoclonal antibody against the alpha 3 integrin subunit, and to a lesser extent by monoclonal antibodies against the beta 1 and alpha 2 integrin subunits. An anti-alpha 5 monoclonal antibody and normal mouse IgG were ineffective as inhibitors of tumor cell adhesion to the peptide. Two cell surface proteins of 120 and 150 kDa bound to an alpha 1(IV)531-543 peptide affinity column and were eluted with 20 mM EDTA. When the eluted proteins were incubated with monoclonal antibodies against either the alpha 3 or beta 1 integrin subunit, proteins corresponding in molecular weight to alpha 3 and beta 1 integrin subunits were precipitated. No proteins were immunoprecipated with monoclonal antibodies against the alpha 2 or alpha 5 integrin subunits. Thus, the alpha 3 beta 1 integrin from two tumor cell types has been shown to bind directly to the alpha 1 (IV)531-543 peptide. The alpha 1(IV)531-543 peptide is the first collagen-like sequence that has been shown to bind the alpha 3 beta 1 integrin.

Characterization of endonucleolytic activity of HIV-1 integrase using a fluorogenic substrate.

Retroviruses require viral DNA to be synthesized by reverse transcription in the cytoplasm followed by integration of the resulting viral DNA into the host chromosome in the nucleus. Reverse transcription and integration, essential steps in the life cycle of retroviruses, are possible targets in the development of antiviral reagents. One attractive target is the integrase protein, a product of the retroviral pol gene which is solely responsible for the retroviral integration process through cutting and joining reactions. When screening for massive numbers of antiviral agents, a rapid and precise assay is ideal. We report the application of fluorescence resonance energy transfer (FRET) with fluorescein and eosin as the energy transfer pair to characterize HIV-IN-mediated DNA cleavage reactions. Past concerns with applications of FRET to DNA were due to interactions of the fluorophore with the DNA, resulting in quenched fluorescence. However, in this study these concerns have been resolved with the use of a nucleotide analog with a 12-carbon linker arm, 5-amino (12)-2'-deoxyuridine beta-cyanoethyl phosphoramidite. Steady-state fluorescence studies show that cleavage of the fluorogenic substrate by integrase results in enhancement of quenched donor fluorescence intensity. The fluorescence assay was confirmed by autoradiographic analysis of the cleavage reaction with radiolabeled fluorogenic substrate. This fluorescence assay will facilitate both detailed kinetic studies and the rapid screening of novel integrase inhibitors.

Determination of the monomer-dimer equilibrium of interleukin-8 reveals it is a monomer at physiological concentrations.

Interleukin-8 has been shown by X-ray crystallography and NMR to be a homodimer, suggesting that this is the form which binds to its receptor. Here we measure, for the first time, the monomer-dimer equilibrium of interleukin-8 using analytical ultracentrifugation and titration microcalorimetry and find that it dissociates readily to monomers with an equilibrium dissociation constant of 18 +/- 6 microM at 37 degrees C. The present findings suggest that the monomer is the form which binds to the receptor. Comparison of experimental and structure-based calculated thermodynamics of interleukin-8 dimerization argues for limited subunit conformational changes upon dissociation to monomer.

Characterization of the tryptophan fluorescence and hydrodynamic properties of rat DNA polymerase beta.

We have examined the biophysical properties of DNA polymerase beta (beta-pol) in solution. Time-resolved and steady-state fluorescence were used to investigate the microenvironment of the lone tryptophanyl residue (Trp324), and a combination of sedimentation equilibrium, sedimentation velocity and fluorescence anisotropy decay measurements were used to study the hydrodynamic properties of the enzyme. Trp324 appears to be exposed to water as judged by the tryptophan emission and steady-state and lifetime quenching experiments. The fluorescence is easily quenched by a neutral quencher acrylamide (kq = 1.59 x 10(9)M-1S-1), and by a negatively charged ionic quencher, I- (kq = 1.60 x 10(9) M-1S-1), but not by a positively charged ionic quencher, Cs+ (kq = 0.2 x 10(9) M-1S-1). The fluorescence lifetime of beta-pol is best described by the sum of two exponentials with a longer lifetime component of 8.4 ns and a shorter lifetime component of 1.3 ns. Decay associated spectra (DAS) show emission maxima at 340 nm and at 345 nm for the shorter lifetime and longer lifetime components, respectively, with corresponding centers of gravity at 347 nm and 348 nm. Sedimentation equilibrium experiments show that the enzyme exists as a monomer at the KCl concentrations (> 0.05 M) studied in the absence of divalent metals. Zn2+ causes higher order aggregation, but no such aggregates are seen with Mg2+ and Mn2+. In the presence of 1 mM manganese, the average lifetime decreased approximately 10%, from 8.14 ns to 7.38 ns, with a concomitant increase of average rotational correlational time (phi) from 24 ns to 28 ns. The accessibility of the positively charged quencher (Cs+) to tryptophan also decreases approximately 50%, indicating alteration of the tryptophan microenvironment. By contrast, Mg2+ causes minor changes in fluorescence properties. The hydrodynamic shape of the intact enzyme and its single-stranded (8 kDa) and double-stranded (31 kDa) DNA binding domains were further investigated by sedimentation velocity measurements. The value of S0(20),W for the intact enzyme is 2.97 S, and the calculated axial ratio is 5.0. In contrast to the 8 kDa domain, which has a less asymmetric shape with an axial ratio of 2.3, the 31 kDa domain shows an elongated structure with an axial ratio of 5.5. These data suggest that the axial ratio of the intact enzyme may be the result of marked bending of the molecule at the flexible hinge region between the two domains.

Actobindin induces the accumulation of actin dimers that neither nucleate polymerization nor self-associate.

Actobindin purified from Acanthamoeba castellanii inhibits the nucleation, but not the elongation, phase of actin polymerization. Previously, we had speculated that actobindin, which can simultaneously bind two actin monomers (Bubb, M.R., Lewis, M.S., and Korn, E.D. (1991) J. Biol. Chem. 266, 3820-3826), might preferentially interact with small oligomers and inhibit their ability to elongate (Lambooy, P.K., and Korn, E.D. (1988) J. Biol. Chem. 263, 12836-12843). In the accompanying paper (Bubb, M.R., Lewis, M.S., and Korn, E.D. (1994) J. Biol. Chem. 269, 25587-25591), we show that under non-polymerizing conditions, actobindin binds to covalently cross-linked actin dimers with higher affinity than to two actin monomers. The sedimentation velocity and fluorescence anisotropy experiments described in this paper show that actobindin prevents the formation of actin oligomers larger than an actin dimer under conditions in which, in the absence of actobindin, actin rapidly polymerizes to F-actin with no detectable small oligomers. Moreover, the molar concentration of actin dimer formed in the presence of actobindin can exceed the total actobindin concentration. These results indicate that actobindin does not form a stable complex with native actin dimer but, rather, causes the accumulation of dimers that are unable to nucleate polymerization or self-associate.

A fluorometric assay for DNA cleavage reactions characterized with BamHI restriction endonuclease.

Fluorescently labeled oligonucleotides and DNA fragments have promise in nucleic acid research with applications that include DNA hybridization, automated DNA sequencing, fluorescence anisotropy, and resonance energy transfer studies. Past concerns with fluorescent-labeled DNA arose from interactions between fluorophores and DNA that result in quenched fluorescence. This quenching phenomenon is most problematic in fluorescence resonance energy transfer studies because quenching of the donor fluorescence could result from either resonance energy transfer or nontransfer effects. In the present study, relief of nontransfer quenching of a 14-mer fluorescein 5-isothiocyanate (FITC)-labeled oligonucleotide containing the BamHI restriction site was characterized with both steady-state and time-resolved fluorescence techniques. The FITC-labeled single strand was best fit by a triexponential decay with lifetimes of 0.5, 2.7, and 4.2 ns. The 4.2-ns component was found to contribute more than 80% of the total steady-state intensity. Upon annealing with an unmodified complementary strand, the contribution from the 4.2-ns component was significantly decreased, resulting in twofold quenching of total fluorescence. We reasoned that this quenching phenomenon should be a reversible process and could be employed to study strand separation processes in molecular biology. Hence, cleavage of the fluorescently labeled substrate was examined using DNAase I and BamHI restriction endonuclease. Our results show that the quenched fluorescence is totally recovered upon cleavage (compared to that of the single strand). The extent of cleavage measured by fluorescence was confirmed by nondenaturing polyacrylamide gel electrophoresis analysis. We believe this fluorescence "dequenching" technique may be used to quantify the kinetics of other DNA strand separation and cleavage processes in molecular biology.

Low-coherence reflectometry for stationary lateral and depth profiling with acousto-optic deflectors and a CCD camera.

We describe a new optical low-coherence reflectometer for depth and lateral scanning without moving parts. The reflectometer covers a range of 0.4 and 1 mm in the depth and lateral dimensions, respectively. This level was accomplished by an acousto-optic deflector for lateral scanning and temporal-coherence gating for depth resolution. The ac component of the reflected light was captured by a cooled 16-bit CCD camera with a special readout scheme. As a proof of principle, optical depths of a staggered stack of glass plates were measured.

Study of the conformation of DARPP-32, a dopamine- and cAMP-regulated phosphoprotein, by fluorescence spectroscopy.

DARPP-32 is a potent inhibitor of protein phosphatase 1 when it is phosphorylated on Thr34 by cAMP-dependent protein kinase. DARPP-32 is also phosphorylated on Ser45 and Ser102 by casein kinase II, resulting in a facilitation of phosphorylation by cAMP-dependent protein kinase. We have studied the conformation of recombinant rat DARPP-32 by steady-state and time-resolved fluorescence. The steady-state emission spectra and quenching of the intrinsic (Trp163) and extrinsic fluorescence (acrylodan or lucifer yellow linked to Cys72) were consistent with a complete exposure of these residues to the aqueous environment. The intrinsic fluorescence of DARPP-32 was resolved into three decay components with lifetimes of 1, 3.4, and 7 ns, with the intermediate lifetime component giving the major contribution. The ratio between the amplitudes associated with the short and long decay constants was decreased upon denaturation. The rotational behavior of DARPP-32 measured by anisotropy decay revealed that Trp163 is located in a highly flexible peptide chain, whereas Cys72 is embedded in a more rigid environment. Phosphorylation by cAMP-dependent protein kinase did not alter any of the fluorescence parameters, whereas only minor effects were associated with casein kinase II phosphorylation. These findings indicate that DARPP-32 contains at least two distinct domains and that phosphorylation has no dramatic effects on its conformation.