Intranuclear Binding Kinetics and Mobility of Single Native U1 snRNP Particles in Living Cells

David Grünwald^*^,, Beatrice Spottke^*, Volker Buschmann^,, and Ulrich Kubitscheck^*

*Institut für Physikalische und Theoretische Chemie, Rheinische Friedrich-Wilhelms-Universität, D-53115 Bonn, Germany; and Max-Delbrück-Centrum, 13125 Berlin, Germany

Submitted June 27, 2006; Revised September 6, 2006; Accepted September 13, 2006
Monitoring Editor: Jennifer Lippincott-Schwartz

ABSTRACT

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Uridine-rich small nuclear ribonucleoproteins (U snRNPs) aresplicing factors, which are diffusely distributed in the nucleoplasmand also concentrated in nuclear speckles. Fluorescently labeled,native U1 snRNPs were microinjected into the cytoplasm of livingHeLa cells. After nuclear import single U1 snRNPs could be visualizedand tracked at a spatial precision of 30 nm at a frame rateof 200 Hz employing a custom-built microscope with single-moleculesensitivity. The single-particle tracks revealed that most U1snRNPs were bound to specific intranuclear sites, many of thosepresumably representing pre-mRNA splicing sites. The dissociationkinetics from these sites showed a multiexponential decay behavioron time scales ranging from milliseconds to seconds, reflectingthe involvement of U1 snRNPs in numerous distinct interactions.The average dwell times for U1 snRNPs bound at sites withinthe nucleoplasm did not differ significantly from those in speckles,indicating that similar processes occur in both compartments.Mobile U1 snRNPs moved with diffusion constants in the rangefrom 0.5 to 8 µm²/s. These values were consistent withuncomplexed U1 snRNPs diffusing at a viscosity of 5 cPoise andU1 snRNPs moving in a largely restricted manner, and U1 snRNPscontained in large supramolecular assemblies such as spliceosomesor supraspliceosomes.

INTRODUCTION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Cell nuclei exhibit a high degree of spatial and functionalorganization of their molecular components (Cremer and Cremer,2001; Misteli, 2005). The question how nuclear factors moveand interact within this well-organized structure, how molecularfactors find their targets, and how trafficking exerts a possibleregulatory function is currently a focus in cell biology (Bubulyaand Spector, 2004; Pederson, 2004; Gorski and Misteli, 2005).An exact quantification of interactions and molecular mobilitiesis the prerequisite for a detailed understanding of the formationof intranuclear structures and the regulation of their functionby modifications of interactions and transport (Gorski et al.,2006).

Eukaryotic pre-mRNA transcripts go through several post-transcriptionalmodifications before their translocation by the NPCs into thecytoplasm (Darzacq et al., 2005). Usually pre-mRNAs have noncodingsequences designated as introns that must be removed from thesequence to yield functional mRNA. This essential biochemicalprocessing is designated as pre-mRNA splicing, which is achievedby intranuclear molecular pre-assembled complexes, the so-calledspliceosomes. Spliceosomes consist of more than 70 differentproteins, many of which are part of the uridine-rich small nuclearribonucleoproteins (U snRNPs), which are classified as U1, U2,U5, and U4/U6, according to their small nuclear RNA (snRNA)content. With the exception of U6, the snRNAs are synthesizedin the nucleus by RNA polymerase II and exported to the cytoplasm,where sets of common and specific proteins bind to the snRNAs(Will and Luhrmann, 2001). After their cytoplasmic assemblyU snRNPs are reimported into the nucleus. Spliceosomes havebeen shown to be subcomplexes of huge multicomponent nuclearRNP complexes, so-called supraspliceosomes. Purified by densitygradient centrifugation they sedimented as 200S complexes (Sperlinget al., 1985; Spann et al., 1989) with a mass of 21 MDa (Mulleret al., 1998). Three-dimensional image reconstruction of isolatedsupraspliceosomes revealed a geometric extension of 50 x 50x 35 nm³ (Sperling et al., 1997; Medalia et al., 2002).

The spatiotemporal distribution of splicing factors within cellnuclei is an important example of the functional organizationof the cell nucleus (Lamond and Spector, 2003). Fluorescencelabeling of splicing factors such as ASF/SF2 or U snRNPs revealsnumerous irregular, punctuate structures distributed on a morehomogeneous background within cell nuclei. These fluorescentstructures are formed by the enrichment of splicing factorsin subnuclear structures such as interchromatin granule clustersand perichromatin fibrils collectively designated as splicingfactor compartments or speckles. The functional role of specklesis still unresolved. Possible functions include splicing factorreprocessing sites or storage spaces regulating the level offree and active factors. Another hypothesis is that in specklessplicing factors are assembled together with other componentsof the transcription and RNA processing machinery into supramolecularcomplexes, whereas the dispersed splicing factors might representactive complexes involved in cotranscriptional splicing.

In the last few years large efforts have been undertaken togain insight into intranuclear mobility and interactions ofintranuclear molecular components—DNA-binding proteins,splicing factors, and RNP particles. The experimental approachesmostly used were fluorescence correlation spectroscopy (FCS;Brock et al., 1998; Politz et al., 1998, 2006; Schwille et al.,1999; Wachsmuth et al., 2000), and fluorescence recovery afterphotobleaching (FRAP) or photoactivation (PA) combined withmathematical modeling (Seksek et al., 1997; Houtsmuller et al.,1999; Kruhlak et al., 2000; Lukacs et al., 2000; Phair and Misteli,2000; Verkman, 2002; Carrero et al., 2003; Braga et al., 2004;Phair et al., 2004; Beaudouin et al., 2006). In addition tothese established techniques, recently single-particle imagingbased on state-of-the-art videomicroscopy has proven its powerto visualize details of trafficking within the cell nucleusin a sequence of publications (Goulian and Simon, 2000; Kueset al., 2001a, 2001b; Seisenberger et al., 2001; Babcock etal., 2004; Shav-Tal et al., 2004; Bausinger et al., 2006).

The results obtained so far must be discriminated accordingto analysis of tracer molecule mobility and studies focusingon functionally active proteins or RNPs (see review, Gorskiet al., 2006). Inert tracer molecules usually show diffusioncoefficients within cell nuclei $~$ 4–15 times smaller thanaqueous solution (Lang et al., 1986; Seksek et al., 1997; Bragaet al., 2004). Usually, biologically active molecules were reducedin their apparent mobility by a factor of 10–100 comparedwith aqueous solution (reviewed by Houtsmuller and Vermeulen,2001; Verkman, 2002; Gorski et al., 2006). The significant reductionof mobility was interpreted to indicate frequent, but transientinteractions of the examined molecular factors with numerouslargely immobile intranuclear structures. Obviously, the motionof nuclear proteins, RNA molecules, or RNP particles reflectstheir intranuclear function. Surprisingly, the GFP conjugateof ASF/SF2 showed the same mobility independently of whetherit was associated with speckles or dispersed in the nucleoplasm(Kruhlak et al., 2000). In accordance to this work, it was recentlyfound that the mobility of poly(A) RNA did not differ betweenspeckles and nucleoplasm in HeLa cell nuclei (Politz et al.,2006).

In the last few years single-molecule tracking (SMT) by high-speedfluorescence videomicroscopy has evolved to a routine methodin the biosciences (Schwille and Kettling, 2001; Moerner, 2003;Sako and Yanagida, 2003; Tinnefeld and Sauer, 2005). It stillappeared debatable, however, whether the time resolution attainableby high-speed cameras was really high enough to follow the trajectoriesof single protein molecules within the cellular interior. Recently,we demonstrated the imaging and tracking of single protein moleculesin physiological buffer at frame rates of $~$ 350 Hz (Grunwald etal., 2006). Analysis of the single-molecule trajectories yieldedthe same diffusion constants as control measurements performedby FCS. Considering the generally higher intracellular viscosity,it was thus proven that the tracking of proteins inside livingcells is faithfully possible if frame rates in the range of100 frames per second or higher can be achieved. Previouslywe used single-molecule imaging for analyzing the movementsof a recombinant $beta$ -galactosidase protein (Kues et al., 2001b)and of the splicing factor U1 snRNP (Kues et al., 2001a) indigitonin-permeabilized cells with maximum frame rates of 35Hz. These cells represented a system, which still containedintracellular structures as geometric constraints on mobility,but presumably not the functionally intact DNA and RNA processingcomplexes.

In the current study we applied single-molecule tracking tostudy the intranuclear dynamics of a biologically active splicingfactor in live cells. We microinjected fluorescently labeledsplicing factors U1 snRNPs into the cytoplasm of living cellsand therefore maintained their biochemical functions, integrity,and the structure of the nuclei. The splicing factors were importedinto the nucleus by nucleo-cytoplasmic transport. Imaging wasperformed using a fast and sensitive electron-multiplying CCD(EMCCD). Using this camera we could follow the movements ofU1 snRNPs in real time, but could also focus on slow eventsby reducing the imaging frame rate. We found that U1 snRNPsmoved with diffusion coefficients in the range of 0.5–8µm²/s. Although long-distance movements of U1 snRNPs couldclearly be observed, transient binding to immobile sites wasthe dominating process. The dissociation kinetics from thesebinding sites was analyzed on different time scales rangingfrom milliseconds to seconds. Our data provided new insightinto the molecular dynamics of a functional ribonucleoproteinparticle within living cells.

MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Reagents and Buffers
Cy5-labeled U1 snRNPs were prepared as described in Huber etal. (1998). Purity, functionality, and integrity of labeledU1 snRNPs were confirmed as described in Marshallsay and Luhrmann(1994). Before final use in microinjection experiments U1 snRNP-Cy5were diluted and centrifuged in transport buffer (50 mM HEPES/KOH,pH 7.3, 110 mM potassium acetate, 5 mM sodium acetate, 2 mMmagnesium acetate, 1 mM EGTA, 2 mM DTT). The plasmid codingfor fusion proteins of ASF/SF2-GFP was a kind gift from JudithSleeman.

Cell Culture and Transfection
HeLa cells were grown in DMEM supplemented with 10% FCS. Forlive cell analysis cells were seeded on cover glasses. As referencelabel for the nuclear speckles cells were transfected with plasmidscoding for fusion proteins of ASF/SF2-GFP (Sleeman et al., 1998)using an Effectene transfection kit (Qiagen, Hilden, Germany)1 d after seeding. Microscopic analysis was performed in a custom-builtsample holder at room temperature 24 h after transfection toallow expression of fusion proteins.

Single-Molecule Microscopy
Single-particle tracking (SPT) experiments were performed usinga custom-built single-molecule microscope based on a Zeiss Axiovert100TV equipped with a 63x NA 1.4 oil immersion objective lens(Jena, Germany; Kubitscheck et al., 2005). Green fluorescencewas excited by an Ar⁺-Laser emitting at 488 nm, and red fluorescencewas excited by a HeNe-Laser emitting at 632.8 nm. Laser illuminationwas switched on only during image acquisition by means of anacousto-optical tunable filter. For single-particle image acquisitionwe used the iXon DV 860 BI camera (Andor Technology, Belfast,Northern Ireland) in combination with a 4x magnifier yieldinga pixel size in the object space of 95.24 nm. Microinjectionof U1 snRNPs was carried out with an Eppendorf injection andmicromanipulation setup using an injection time of 1 s at aninjection pressure of 100 hPa and a holding pressure 15 hPa.Single-particle imaging was started 10 min after microinjectionof U1 snRNPs into the cytoplasm to allow cells to recover. Cellrecovery was monitored by examining the cellular morphologyin bright-field mode by digitally contrast-enhanced imaging.Before acquisition of the movies a focal plane was searchedto optimize the contrast of the GFP-labeled nuclear speckles.After taking an image in the green channel with a Zeiss AxiocamMRm, movies recorded in the red channel illustrated the motionof U1 snRNP-Cy5 after its nuclear import. Usually 1000 frameswere recorded in a single movie, with integration times of 5and 10 ms and frame rates of k_acq = 5, 10, 100, and 200 Hz.A total of 10 cells was examined, yielding more than 100 singlemovies. The green and red fluorescence channels were scaledand aligned to each other using images of dispersed, immobilizedmulticolor fluorescence beads (TetraSpeck Microspheres, diameter0.1 µm, Molecular Probes, Leiden, The Netherlands).

Image Processing of Video Images
Identification and tracking of the single-molecule signals wasaccomplished using Diatrack 3.0 (Semasphot, North Epping, Australia),a commercial image processing program for the identificationand localization of single-particle signals and trajectories(Vallotton et al., 2003). For tracking a maximal displacementof 10 pixels from frame to frame was allowed. The applicationof the automated data analysis scheme to our data was problematic,because the single-molecule data often displayed low signal-to-noiseratios. Therefore, after Diatrack processing we verified thesingle-particle tracks in the original, unprocessed data byvisual inspection. Intracellular compartments (cytoplasm, nucleoplasm,or speckles) were marked in specific colors using IPLab (ScanalyticsInc., Fairfax, VA), and this false color reference image wasused for compartment assignment of the individual tracks withthe help of user-written macros in Origin 7.5 (Microcal Software,Northhampton, MA). All tracks within the cytoplasm includinga 10-pixel border region near the nuclear envelope were discardedto avoid evaluation of particles during their import into thenucleus. Also, all tracks within a distance of eight pixelsfrom the image border were discarded.

Trajectory Analysis
Each U1 snRNP-Cy5 trajectory was defined as a set of coordinates(x_i, y_i) with 1 $≤$ i $≤$ N, where N denoted the total number of observations.In the case of two-dimensional Brownian motion the mean squaredisplacements, $<$ r²(t_c) $>$ , are related to time and diffusion coefficient,D:

(1)
Thus,a linear relationship between $<$ r²(t_c) $>$ and time indicates Brownianmotion. However, if the motion is not due to free diffusionbut, e.g., to confined diffusion or directed flow, the relationbetween the mean square displacements (MSD) and time is nonlinear(Saxton and Jacobson, 1997). Furthermore, the joint analysisof the trajectories of an ensemble of molecules according toEquation 1 is not suitable when the population contains differentmobility fractions. Such heterogeneous populations are moreappropriately analyzed by a jump distance analysis.

Jump Distance Analysis
The probability that a particle starting at a specific positionwill be encountered within a shell of radius r and width drat time t from that position is for a single species diffusingin two dimensions given as follows (Crank, 1975):

(2)
if we identify the starting position withthe origin. Experimentally, this probability distribution couldbe approximated by a frequency distribution, which was obtainedby counting the jump distances within respective intervals [r,r + dr] traveled by single particles after a given time lag.In cases of particles with multiple diffusive species or particleschanging the mode of motion along their trajectory the jumpdistance distributions cannot satisfactorily be fitted by eq. 2assuming a single diffusion coefficient. Such different mobilityfractions can be detected, and quantified by curve fitting takingseveral diffusion terms into account. E.g., for a jump distancedistribution containing contributions from three species withdiffering diffusion constants,

(3)
where M is related to the number of jumpsconsidered in the analysis, and f₁, f₂, and f₃ designate thefractions with diffusion constants D₁, D₂, and D₃, respectively.

Immobile Particles
For immobile particles the jump distance between two subsequentframes corresponded to a maximum dr_max, which was determinedby the localization precision alone. We defined as dr_max thethreefold localization precision (dr_max = 3 ${sigma}$ _loc ${approx}$ 100 nm). Allparticles that did not jump farther than dr_max between subsequentframes were taken as immobile.

To determine the binding durations, we screened all trajectoriesfor the jump distances between subsequent frames and countedthe number of subsequent steps with jump lengths smaller thandr_max. This number, n, characterized the length of an immobiletrajectory or trajectory segment. For all immobile trajectorysegments identified in this manner, the maximum extensions inthe x and y direction, ${Delta}$ x_max and ${Delta}$ y_max, were determined. All trajectorieswith either ${Delta}$ x_max or ${Delta}$ y_max >150 nm were inspected visuallyto decide whether they were produced by indisputable immobileparticles with a random distribution of the jump directions.This was done to exclude the possibility that several smallersteps into the same direction would finally lead to a significant,sliding movement beyond the localization precision. No trajectoryhad to be rejected because of this criterion. Finally, n wastranslated into a binding time, ${tau}$ , by ${tau}$ = (n + 1)/k_aq. The singlevalues of ${tau}$ were used to calculate a decay curve N( ${tau}$ ) giving thenumber of particles, which were still immobile after time ${tau}$ .

Correction of Photobleaching
Photobleaching was quantified by plotting the average intensityin the cell nucleus as a function of time. Because U1 snRNPswere not exported, the observed fluorescence decay was due tophotobleaching. The fluorescence decay was fitted by a monoexponentialfunction, which yielded a bleaching time constant of ${tau}$ _bl = 120± 30 ms. Hence, 50% of individual U1 snRNPs were bleachedafter the acquisition of 16 images at a single-frame integrationtime of 5 ms, corresponding to a continuous illumination of80 ms. The decay curves N( ${tau}$ ) of bound particles was correctedfor bleaching by N( ${tau}$ )_corr = N( ${tau}$ ) · e^/_bl.

RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Single U1 snRNPs Can Be Visualized and Tracked in Real Time in Live Cell Nuclei
U1 snRNPs labeled by Cy5 were microinjected at a low concentrationinto the cytoplasm of live HeLa cells transiently expressingASF/SF2-GFP. By using very gentle injection conditions the internalstructure of the nuclei was left unaffected by the microinjection,and the particles could be examined in an undisturbed intranuclearenvironment after their nuclear import. According to previouswork (Kleinschmidt and Pederson, 1990) only a very small percentageof the U1 snRNPs introduced into the cytoplasm was expectedto be imported into the nucleus after 10 min, which was thetime when measurements were started. The concentration of theinjected fluorescently labeled U1 snRNPs was chosen such thatthe concentration in the nucleus was in the picomolar range.This extremely low concentration of particles allowed imagingthe particles spatially separated from each other. Using a custom-builtsingle-molecule microscope equipped with efficient laser irradiationand a fast, highly sensitive EMCCD imaging system, single fluorescentRNP complexes could be visualized in real time in the cellularinterior. Thereby high-speed movies of the functioning of singleU1 snRNPs within living cells (see Supplementary Movie 1, OnlineSupplementary Material) could be recorded, which allowed theidentification and extraction of single-particle traces by dedicatedimage processing tools (for details on particle identificationand trajectory extraction, see Materials and Methods). An exampleof the trajectories of single Cy5-labeled U1 snRNPs and theirspatial positions within a cell nucleus are shown in Figure 1.The corresponding Supplementary Movie was recorded at 200 Hz.Figure 1A shows trajectories of numerous single mobile and immobileU1snRNPs. The RNP traces were overlaid to the green fluorescenceimage of the same HeLa cell nucleus expressing ASF/SF2-GFP.The brighter spots marked by dark-gray lines indicated the positionsof splicing factor compartments or speckles. Note that the ASF/SF2-GFPwas not imaged by a confocal but a normal fluorescence microscope.Therefore, the contrast of the speckles was not as high as canbe achieved by confocal imaging (Lamond and Spector, 2003).Plots like this were produced for each acquired single-particlemovie and represented the first qualitative views onto the U1snRNP dynamics within living cell nuclei. Mobile U1 snRNPs aswell as transiently immobilized particles could well be distinguishedand analyzed in the nucleoplasm as well as inside speckles.The white box in Figure 1A marks a region containing a singletrajectory, which was analyzed in detail in Figure 1, B–D.Figure 1B displays the sequence of single frames showing theRNP on its trajectory. A magnified plot of the trajectory isdisplayed in Figure 1C. This plot reveals that the particlemoved to a specific site, resided here for a short time, andthen left the site again. Figure 1D displays the time courseof the fluorescence signal in the attachment region. On approachof the particle, the signal increased from background leveland remained clearly above it for nine images. This illustratedthat the particle remained for 45 ms at the specific positionbefore leaving. In addition, this plot demonstrated the excellentsignal-to-noise ratio (SNR) of single U1 snRNP-Cy5 imaging inthe cell nuclei.

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Figure 1. Trajectories of single U1 snRNPs in a living cell nucleus. (A) Trajectories (black dots connected by black lines) of numerous single U1snRNPs extracted from a single-molecule movie, which was recorded at 200 Hz (Supplementary Movie 1, Online Supplementary Data). The trajectories were plotted over an image of the ASF/SF2-GFP, which was transiently expressed in the respective HeLa cell nucleus. Here, all nuclear trajectories were shown; however, those close to the borders were not evaluated (see Materials and Methods). The brighter spots marked by dark gray lines indicated the positions of speckles. The approximate position of the nuclear envelope was deduced from the limits of ASF/SF2-GFP fluorescence, and indicated by the white line. Mobile U1 snRNPs as well as transiently immobilized RNPs could well be distinguished within nucleoplasm and speckles. The white bar corresponded to 2 µm. The white box marks a region containing a single trajectory, which was scrutinized in B to D. (B) The short image sequence of the trajectory marked in A. The size of a single image was 8 µm². (C) Magnified view of the positions, at which the U1 snRNP was observed, revealing that the RNP moved to a specific site, resided there for a certain time and then left the site again. Please note that the complete field shown corresponds to 1 µm² only. (D) Time course of the fluorescence signal at the attachment region x = 6.77 ± 0.05 and y = 2.67 ± 0.05 µm, which indicated that the particle remained for 45 ms at the specific nucleoplasmic position before leaving.

Single U1 snRNPs Were Predominantly Observed during Binding
Single U1snRNP particles were often observed for longer periodsof time at specific sites such as shown in the example above(Figure 1C). Figure 2A shows a magnified view of a specificregion of a cell nucleus. At numerous positions (see black arrows)single U1 snRNPs were observed for extended periods of timeat specific spots. We examined the geometrical extension ofthese spots by calculating the center of mass of 100 arbitrarilyselected spots in different cells and plotted the distance distributionof the single positions to their respective centers (Figure 2B).This distance distribution could satisfactorily be describedby a Gaussian distribution with a SD of ${sigma}$ _exp = 30 ± 5nm. It should be noted that the position measurement of a singleparticle or molecule necessarily has a limited precision, whichis defined by the SNR and other parameters, such as pixel sizeand magnification of the microscope (Kubitscheck et al., 2000

;Thompson et al., 2002

). The fundamental cause for the limitedprecision is the photon noise of the single-molecule fluorescenceemission. Hence, for a completely immobile molecule, the measuredposition has a specific variation upon repetition of the measurement,which is designated as localization precision. This localizationprecision can be estimated by theoretical and experimental meansand yielded for the SNR values of 5–10 obtained by usin the cellular interior a value of ${sigma}$ _theo = 20–25 nm (Kubitschecket al., 2000

). Hence, the single U1 snRNPs, which appeared repetitivelyat distinct positions within the nuclei, showed a positionalvariation almost identical to that of completely immobile particles.We can conclude that these particles were firmly attached togeometrically well-defined, specific sites over the respectiveobservation time.

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Figure 2. The majority of single U1 snRNPs was in a bound state. (A) Magnified view of a specific region of a cell nucleus. At many positions as marked by black arrows single U1 snRNPs were observed for extended periods of time at specific sites; scale bar, 1 µm. (B) The distance distribution of the single positions of 100 randomly selected immobile trajectories to their respective centers could well be described by a Gaussian distribution with a SD of 30 nm (dashed line). A slight deviation between fit and histogram occurred at distances greater than 60 nm.

Dwell Times of Single U1 snRNPs at Their Binding Sites
Movies of the intranuclear U1 snRNP dynamics revealed that bindingdurations of individual particles varied significantly rangingfrom milliseconds to seconds. However, single-particle fluorescencecould only be observed in a limited number of frames beforefinal photobleaching. The average frame number over which singleU1 snRNPs could be observed was 12. Therefore, photobleachingmade the direct observation of long binding events with a highframe rate difficult. To obtain a more complete view of theU1 snRNP binding events, we acquired movies at different framerates k_acq ranging from 5 to 200 Hz.

For immobile particles the lateral distance between two subsequentobservations was defined solely by the localization precision.To account for all immobile particles, we defined a maximumstep size dr_max, the threefold localization precision (dr_max= 3 ${sigma}$ _exp ${approx}$ 100 nm). All particles that did not move beyond dr_maxbetween subsequent frames were regarded as immobile, and 99.7%of all immobile particles were taken into account by this criterion.

For determination of the binding durations the jump distancesbetween subsequent frames were screened, and the number of subsequentsteps with jump lengths smaller than dr_max was counted. Thisnumber n corresponded to the length of an immobile trajectorysegment. Finally, the number of jumps in sequence n for whichthe particles did not move was translated into a binding time ${tau}$ , with ${tau}$ = (n + 1)/k_acq. These data were used to construct adecay curve N( ${tau}$ ) quantifying the number of molecules, which werestill bound at a specific site after time ${tau}$ . Such decay curveswere determined from all movies obtained with a given k_acq forintranuclear binding sites within and outside speckles. Finallythe decay curves were corrected for photobleaching of the U1snRNPs (see Materials and Methods).

Figure 3, A–D, shows the resulting decay curves N( ${tau}$ ) quantifyingthe dissociation of U1 snRNPs from the putative binding sitesobserved at imaging rates of 200, 100, 10, and 5 Hz. The decaycurves were determined for the nucleoplasm ( ${circ}$ ) and speckles ( $bullet$ ).The decay kinetics did not comply with monoexponential functions,but fits using double-exponential decay functions yielded forall data sets satisfactory results (full and dotted lines inFigure 3, A–D, respectively). From the fits we calculatedthe weighted averages of the respective decay times ${tau}$ _ave andplotted these as a function of the cycle time (inverse of theframe rate) in Figure 3E. Obviously, the average decay timesfor nucleoplasm and speckles did not differ much, indicatingcomparable dwell times of U1 snRNPs in both nuclear domains.However, it was remarkable that the dwell times were not constantfor different cycle times, but on the contrary depended on thetime scale at which the binding was analyzed. Obviously thedissociation of U1 snRNPs from their intranuclear binding sitescould not be described by a simple bimolecular dissociationkinetics. The unusual kinetics is discussed thoroughly below.

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Figure 3. Binding duration of immobile U1 snRNPs. (A–D) The curves quantify the dissociation of U1 snRNPs from binding sites observed at 200, 100, 10, and 5 Hz as indicated in the graphs. The axis labels given at the left hand axis refer to the nucleoplasmic binding ( ${circ}$ ), and the labels at the right hand axis refer to the binding in speckles ( $bullet$ ). The lines show the results of fits to the data using a sum of two exponentials. Dotted lines, the fits to the nucleoplasm data; solid lines, fits to the speckle data. (E) The averaged decay times as determined by the fits in A–D were determined and plotted as a function of the image cycle time. Obviously the binding times were related to the time scale, at which the binding was analyzed.

Intranuclear Mobility of U1 snRNPs
The movie data (see Online Supplementary Material, SupplementaryMovie 1) and Figures 1 and 2 demonstrate that U1 snRNPs weremostly observed in an immobile, obviously bound state. However,the high-speed movies also show numerous clearly mobile U1 snRNPs,from which direct information on the mobility characteristicsof intranuclear U1 snRNPs could be obtained. Supplementary Movie2 shows an example of a mobile U1 snRNP, the single frames ofthe sequence that are shown and analyzed in Figure 4. This mobileU1 snRNP was observed in 10 subsequent frames in a sequenceacquired at 100 Hz with an integration time of 5 ms per frame.The particle was moving within the nucleoplasm (for an overlaywith the ASF-GFP image, see Supplementary Figure 1 in the OnlineSupplementary Material). Figure 4A shows the single frames,which were filtered and background subtracted to enhance theparticle contrast. Figure 4B displayed the line profile of theparticle. The profile demonstrated that an unambiguous identificationof the particle above the background noise was straightforward.The complete trajectory of the particle is shown in Figure 4Cin a magnified view, whereas the MSDs of this trajectory wereplotted as a function of time in Figure 4D. A linear fit tothese data according to Eq. (1) yielded a diffusion constantof D = 6.3 ± 0.6 µm²/s.

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Figure 4. Trajectory analysis of a typical mobile U1 snRNP. (A) The frames show the trajectory of a typical mobile U1 snRNP. The position of the U1 snRNP was marked by an arrow. Sequence from a movie taken with 100 Hz and a frame integration time of 5 ms. Original images were smoothed by a Gaussian kernel (2 pixel radius), and the background was subtracted (rolling ball, r = 20) for display here; original and filtered data to this particle are available online; see Supplementary Movie 2. Full field: (128 pixel)² corresponding to (12.2 µm)². (B) Line intensity profile through the position indicated in frame 6 of the sequence. (C) Trajectory of the particle in a magnified view. Please note that the complete field shown corresponds to 9 µm². (D) Mean square displacements of the single-particle trajectory as a function of time. A linear fit to these data yielded a diffusion constant of D = 6.3 ± 0.6 µm²/s. The deviations from linearity for higher MSD values were due to the fact that a trajectory formed by only 10 positions was evaluated.

To obtain a more general characterization of the U1 snRNP mobility,we analyzed the distances covered by the U1 snRNPs between subsequentframes, the so-called jump distances (Smith et al., 1999). Figure 5shows the jump distance distributions for all U1 snRNPs, whichwere observed within the nucleoplasm in the movies acquiredat 100 Hz. Such distributions can be described by Eq. (2), ifthey are due to particles diffusing with a single diffusioncoefficient (see Figure 6 in Kues et al., 2001b

). However, thedistribution shown in Figure 5 could not at all be fitted assuminga single diffusion coefficient (Eq. 2), in contrast to jumpdistance distributions of molecules diffusing in buffer solution(Kubitscheck et al., 2000

; Grunwald et al., 2006

). For the datadisplayed in Figure 5 the minimum number of three diffusionterms was required for an acceptable fit. The fitting resultswere indicated by the lines in Figure 5. The major fraction,f₁, corresponded to particles, which moved with a variance of(50 nm)², a value close to the experimental localization precision(see legend of Figure 2). Hence, these particles did not showsignificant jumps beyond the localization precision and correspondedto those particles, which were identified above and discussedas particles attached to binding sites. Besides the dominatingimmobile fraction, two mobile fractions, f₂ and f₃, could beidentified, which moved with diffusion coefficients of D₂ =0.51 ± 0.05 µm²/s and D₃ = 8.2 ± 3 µm²/s.The area under the curves corresponded to the relative sizesof the three fractions, and yielded 77.5, 15, and 7.3% for f₁,f₂, and f₃, respectively.

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Figure 5. U1 snRNP mobility within the nucleoplasm of living cells. Jump distance distribution for all single U1 snRNPs, which were identified and tracked within the nucleoplasm in the movies acquired at 100 Hz. A minimum number of three diffusion terms was required for an acceptable fit of the data. The largest fraction (long dashes, 77.5%) corresponded to particles, which were immobile. In other words, they performed only a virtual movement caused by the limited localization precision. Here, we obtained a value of ${sigma}$ _immob = 50 nm. These jumps were done by those particles, which were above identified as particles involved in a binding process (Figures 2 and 3). Two particle fractions, f₂ and f₃, corresponded to fast diffusional motion with diffusion coefficients of D₂ = 0.51 ± 0.05 µm²/s (short dashes, 15%) and D₃ = 8.2 ± 3 µm²/s (dotted line, 7.3%). The sum of these fractions yielded an excellent description of the data (full line). The inset shows the same plot with a magnification of the y-scale in order to demonstrate the significant number of large jumps due to particles moving with D₃.

The nucleoplasm corresponded to 90–95% of the observedintranuclear area of the various analyzed cell nuclei. The speckleshad limited sizes corresponding to an average diameter of 0.5–1.5µm, and in sum they covered 5–10% of the availablearea in a typical nucleus. Because of their limited geometricalextension and irregular shapes, it was very improbable to observejumps covering distances greater than 0.5 µm within thesedomains, although they occurred now and then (see Figure 1A).Hence, a quantitative analysis of a jump distance histogramwas not reasonable. Above we defined a maximum jump distancefor immobile particles as the threefold value of the localizationprecision, dr_max ${approx}$ 100 nm. Therefore the fraction of mobile moleculescan be estimated by considering jumps over distance greaterthan dr_max. Within the speckles, we found 17% of all jumps tobe greater than dr_max, whereas within the nucleoplasm, 24% ofall jumps were greater than dr_max (see Figure 5). The reductionfrom 24 to 17% for nucleoplasmic space in comparison to specklescan be attributed to the limited geometric extensions of thespeckles. Therefore, at this qualitative level there was noindication of a mobility reduction of U1 snRNPs within speckledomains.

DISCUSSION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In this study we analyzed the dynamics of U1 snRNPs within livecells at the single-particle level. The used particles wereisolated from HeLa cell nuclei and then labeled by Cy5. Hence,our experiments refer to native RNPs, avoiding the potentialproblems of in vitro–assembled particles, which mightbe incomplete or dysfunctional. We microinjected Cy5-labeledU1 snRNPs at such low concentration into the cytoplasm of livingHeLa cells that we could visualize single U1 snRNPs and tracktheir movements within the cell nucleus after their nuclearimport. Real-time imaging was achieved by a custom-built single-moleculemicroscope equipped with laser illumination and a fast EMCCDfor fluorescence detection. The examined HeLa cells transientlyexpressed ASF/SF2-GFP so that the particle dynamics could bestudied within and outside nuclear speckles. The SNR of theU1 snRNP signals was in the range of 5–10, so that theycould be localized by SPT techniques with a spatial precisionof roughly 30 nm. Using automatic image analysis procedures,we extracted the traces of numerous single mobile and immobileU1snRNPs, which could be overlaid to the ASF/SF2-GFP imagesof the corresponding cell nuclei.

The great majority of observed single U1 snRNPs was in a boundstate. Almost 80% of the U1 snRNPs observed in two subsequentimage frames did not move significantly. This was in stark contrastto an inert, unfunctional tracer molecule inside cell nuclei(D. Grünwald, R. Martin, V. Buschmann, H. Leonhardt, U.Kubitscheck, and M. C. Cardoso, unpublished data), which showeda much greater mobile fraction. Presumably, the immobilizationwas caused by interactions with large, immobile molecular structures.Obviously, being associated to large molecular structures isthe standard state of a splicing factor such as U1 snRNP. Thecorresponding binding sites were very well defined, becausethe particles did not move significantly beyond the experimentallocalization precision. The bound RNPs were attached at fixedsites, and they did not sway or move slowly during their binding.Such small-range movements could be excluded, because the immobilizedsingle U1 snRNPs showed a positional spreading only 5–10nm greater than that, which would theoretically follow fromtheir SNR. This insignificant increase was probably due to theintranuclear fluorescence background. We assume that the observedimmobilization of the U1 snRNPs was often caused by the involvementof the particles in ongoing splicing events. This assumptionwas suggested by the fact that in a previous study using digitonin-permeabilizedcells, which were largely physiologically inactive, a significantlysmaller immobile fraction of U1 snRNPs was found, namely only22% (Kues et al., 2001a). Pre-mRNA splicing is occurring oftencotranscriptionally (Melcak et al., 2000). This means that anextremely large DNA/RNA–protein complex is formed, whichwould certainly not have a notable mobility, but would ratherrepresent a large, anchored supramolecular complex.

The dissociation from the binding sites showed a surprisingkinetics. Obviously the dissociation times were dependent onthe time resolution of observation. Analyzing binding at highfrequency, we observed short binding durations, whereas whenobserving binding at low frame rate, we obtained long bindingdurations. This was consistent with the fact that we obtainedtwo decay times for each time range analyzed. This already indicatedthat complex interactions were observed. Altogether, dissociationtimes ranging from 5 ms to 1400 ms were obtained. In case ofa simple molecular dissociation reaction one would expect amonoexponential decomposition of initially existing complexeswith a single dissociation time constant. Our data showed thatthe interaction of U1 snRNPs with their intranuclear bindingpartners was not a simple bimolecular interaction. The dissociationof U1 snRNPs from binding sites occurred over a wide time scale,which reflected the extremely complex way, in which U1 snRNPswere interacting with additional molecular components. Possiblywe perceived—besides short nonspecific interactions, moleculartrapping in a chromatin network on the one hand and genuinesplicing events on the other hand—further processes, suchas assembly of spliceosomes before splicing and postsplicingprocessing (Darzacq et al., 2005). We think that a decay kineticson many different time scales is a fundamental property of recognitionevents and reactions of multistep molecular interaction systems(Phair et al., 2004). In the splicing reaction, a large numberof different molecular components must act together, which arepreassembled in the form of spliceosomes and supraspliceosomes,which comprise U1 snRNPs (Muller et al., 1998; Azubel et al.,2006). In addition, a great number of different splicing reactions—simpleand more complex ones—are taking place simultaneouslywithin a cell nucleus. Therefore, a single dissociation constantcould actually not be expected.

We quantified the kinetics of dissociation within and outsidespeckles. Speckles were defined on the basis of ASF/SF2-GFPfluorescence, and distinct spots of strong GFP fluorescencewere interpreted as speckles. Unfortunately, our microscopewas not an optical sectioning microscope. Nonconfocal videomicroscopyresulted in a rather diffuse appearance of the speckles andmade the clear identification of speckle borders difficult.On the basis of the chosen speckle and nucleoplasm definitions,the dissociation kinetics on short and long time scales didnot differ significantly for binding within the speckles comparedwith the remaining nucleoplasm (Figure 3E). This finding supportedthe results of Kruhlak et al. (2000), who did not detect majordifferences in the dynamics of ASF/SF2-GFP in nucleoplasm andspeckles. It could be concluded that the increase in splicingfactor concentration within the speckles was not due to an increaseddwell time of U1 snRNPs at intraspeckle sites. There remaintwo possible explanations for the higher concentrations of splicingfactors within speckles. First, the on-rate of the interactionis enhanced, which might be caused by a enhanced accessibilityof splicing factors to the speckles in comparison to the remainingnucleoplasm. Second, the density of interaction sites is higherthan in the remaining nucleoplasmic space, whereas the interactionis of similar nature. The latter hypothesis is supported byelectron microscopic results (Puvion and Puvion-Dutilleul, 1996;Lamond and Spector, 2003). We interpreted a part of the observedbinding sites as sites of on-going transcription. Together withthe above observation this would suggest that splicing is takingplace also in speckles, as was previously found by various researchers(Wei et al., 1999; Melcak et al., 2000; Shopland et al., 2002).However, a clear-cut statement on this question is problematic,because the fluorescence microscopic discrimination betweeninterchromatin granule clusters forming the speckled compartmentsand highly active transcription sites with increased levelsof pre-mRNA splicing factors is problematic (Lamond and Spector,2003).

Altogether, the reason for the complex immobilization couldnot yet finally be resolved. However, the large difference inthe size of the interacting U1snRNP fraction in live cells comparedwith digitonin-permeabilized cells (Kues et al., 2001a) underscoresthe requirement of live cell measurements when studying suchintricate physiological processes. Further studies using inhibitionof transcription respectively splicing will provide more insightinto the functional relevance of immobilization events.

Finally, it should be noted that dissociation data like thatshown in Figure 3 are usually available only by a special synchronizationof the molecular complexes in the initial, associated state.This often presents a problem, which is very difficult or impossibleto solve, especially when working in vivo. Single-molecule detection,however, can elegantly resolve this problem. The accumulationof the data here took advantage of a special feature of single-moleculeresearch: the observation of individual molecular interactionevents did not require a synchronization of a molecular ensemble(Weiss, 1999), because the individual events could be alignedin time a posteriori (Kubitscheck et al., 2005).

The presented data created an entirely new view of the moleculardynamics of a functional molecular entity during ongoing liveprocesses. In almost all recent studies on the mobility of functionalmolecules within cell nuclei binding processes were postulatedand accordingly modeled in order to account for mobility dataobtained by photobleaching, photoactivation, or FCS techniques(Wachsmuth et al., 2000; Houtsmuller and Vermeulen, 2001; Carreroet al., 2003; Wachsmuth et al., 2003; Phair et al., 2004; Beaudouinet al., 2006). However, often models of anomalous diffusionwere also able to explain the data (e.g., Wachsmuth et al.,2000). In this study using single-particle tracking bindingevents could unambiguously be observed and thus be proven andbe discriminated from other modes of motion. We did not onlyobserve distinct binding events, but could also measure thedurations of individual interactions. Thereby we found thatthe kinetics of dissociation cannot be described by a singledissociation constant, but rather ranges over more than threeorders of magnitude.

Single-molecule microscopy is especially well suited to followmolecular traces in time (Saxton and Jacobson, 1997). Recentlywe demonstrated that a frame rate of 350 Hz was sufficient totrack single protein molecules such as antibodies and streptavidinmolecules in buffer exhibiting diffusion coefficients as highas 40 and 80 µm²/s, respectively. Therefore we could assumethat the maximum repetition rate of 200 Hz used in this studywas high enough to track the U1 snRNPs with a molecular weightof 240 kDa in real time, especially because a 5- to 10-foldmobility reduction in cells compared with buffer solution couldbe expected according to previous FRAP studies (Lang et al.,1986; Seksek et al., 1997; Braga et al., 2004). By analyzingthe jumps of single U1 snRNPs between subsequent frames, weobtained a general insight into the dynamic behavior of theparticles within the cell nuclei. As shown already by previousstudies using FCS and SPT the mobility of single molecules withincell nuclei cannot be characterized by simple Brownian motion(Goulian and Simon, 2000; Wachsmuth et al., 2000; Kues et al.,2001b). We could discriminate one immobile and at least twomobile fractions. We want to emphasize here that the dissectionof the jump distance distribution into three fractions representeda minimum number. Three fractions were sufficient to fit thedata in Figure 5. However, the fit could have been further improvedby assuming more than three fractions. For the following discussionof the mobile fractions one should also keep in mind that thefractions do not resemble different particles with distinctmobilities. Rather—as could be noted in the trajectoryanalyzed in Figure 1C—single particles switched theirmode of motion along their trajectory. Hence, the fractionsidentified in the jump distance histograms represent differentmodes of motion of possibly identical particles. Altogether,we suppose that distinct mobility fractions do not exist, butrather that the U1 snRNP mobility ranges from 0.5 to 8 µm²/sin a continuous distribution.

In the mobility analysis particles with mobilities ranging from0.5 to 8 µm²/s were observed. A diffusion coefficientof 8 µm²/s is four- to fivefold lower than that expectedfor a 240-kDa protein in aqueous solution. A fourfold reductionin mobility was also found in previous mobility studies of tracermolecules within cell nuclei performed by FRAP (Seksek et al.,1997). Therefore, we assume that the high mobility was shownby uncomplexed U1 snRNPs, which moved within nuclei as in asolution with an effective viscosity of 5 cPoise compared withaqueous buffer of 1 cPoise. In vivo all U snRNPs are centralcomponents of preformed complexes designated as spliceosomes.It has been shown that these complexes occur in a structuretermed supraspliceosome, which contains four native spliceosomes,with a total mass of 21 MDa and dimensions of 50 x 50 x 35 nm³(Sperling et al., 1997; Muller et al., 1998; Medalia et al.,2002). Such complexes, if moving by unrestricted Brownian motion,would have a diffusion constant of about D = 2 µm²/s ina solution of 5-cPoise viscosity. This value for supraspliceosomeslies in the range of diffusion constants determined for mobileU1 snRNPs. It is very unlikely that large objects like supraspliceosomeswould move in an unrestricted manner within the molecular crowdedintranuclear space. Rather, they would be prone to multiplecollisions or interactions with chromatin or other large structures,which would slow it down. This has been reported for large dextranmolecules with a molecular mass of 580 kDa to 2 MDa. Their mobilitywas dependent on the concentration of intracellular obstacles(Seksek et al., 1997). Furthermore, it has been shown that chromatinregions represent a significant obstruction for the accessibilityof large probe molecules (Gorisch et al., 2003). Hence, jumpscorresponding to a mobility as low as D = 0.5 µm²/s couldwell correspond to uncomplexed U1 snRNPs or to U1 snRNPs containedin spliceosomes and supraspliceosomes tumbling in a hinderedmanner through the nucleoplasm.

The established way to analyze intracellular mobility is byFRAP, which measures bulk mobility on a spatial scale of severalmicrometers in a time window of a few to 50 s. On the otherhand, SPT quantifies mobility of individual molecules on lengthscales significantly smaller than 1 µm in time windowsof milliseconds to seconds. It is not straightforward to extrapolatefrom the single-molecule data to the results of FRAP measurements.To accomplish this a respective simulation of bulk mobilityon the basis of the single-particle data would be required,which has not been done yet. However, we can correlate our resultswith FRAP results in the following manner. FRAP detected a three-to fivefold reduction in D for larger tracer molecules withinthe nuclei and a significantly more pronounced reduction formolecules with specific intranuclear interactions (Gorski etal., 2006). Our SPT data also reveal a four- to fivefold reductionin D for mobile, noninteracting, and up to an 70-fold reductionfor presumably interacting U1snRNPs. Finally, we obtained avery detailed and quantitative view to the interactions of aU1snRNP with immobilizing binding partners on a subsecond timescale.

Single-molecule microscopy and single-particle tracking permitsa completely new view to intracellular dynamics. It shows thatsplicing factor dynamics inside living cells is extremely complex.U snRNPs move freely, are incorporated into huge supramolecularcomplexes such as supraspliceosomes, attach to binding sitesfor extended periods of time, and are released again. Bindingand dissociation occurs obviously under widely varying kineticconditions. A detailed analysis of long single-particle trajectories,use of several fluorescent labels in parallel, and the combinationwith complementary techniques such as FCS and quantitative photobleachingtechniques will provide further insights into complex in vivoprocesses such as RNA processing.

ACKNOWLEDGMENTS

U.K. is heavily indebted to Reiner Peters for using numerousexperimental facilities in his lab, and thanks M. Cristina Cardosofor helpful discussions and Jan-Peter Siebrasse for criticalreading of the manuscript. U.K. gratefully acknowledges financialsupport by the Volkswagen Foundation (Grant I/78852) and theGerman Research Foundation (Grant Ku 975/3-3).

Footnotes

This article was published online ahead of print in MBC in Press(http://www.molbiolcell.org/cgi/doi/10.1091/mbc.E06-06-0559)on September 20, 2006.

The online version of this article contains supplementalmaterial at MBC Online (http://www.molbiolcell.org).

Present addresses: Department of Anatomy and Structural Biology,Albert Einstein College of Medicine, Bronx, NY 10461;

PicoQuant GmbH, Rudower Chaussee 29, 12489 Berlin, Germany.

Address correspondence to: Ulrich Kubitscheck (u.kubitscheck{at}uni-bonn.de)

Abbreviations used: ASF, alternative splicing factor; EMCCD, electron multiplying CCD; FCS, fluorescence correlation spectroscopy; FRAP, fluorescence recovery after photobleaching; MSD, mean square displacements; SPT, single-particle tracking; snRNA, small nuclear RNA; MSD, mean square displacements; U snRNP, uridine-rich small nuclear ribonucleoprotein

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