Effect of changing vascular volume on measurement of protein reflection coefficient in ischemic lungs

In ischemic organs, the protein reflection coefficient (sigma) can be estimated by measuring blood hematocrit (Hct) and protein after increasing static vascular pressure (P(v)). Our original equation for sigma (J Appl Physiol 73: 2616-2622, 1992) assumed a constant vascular volume during convective fluid flux (). In this study, we 1) quantified the rate of vascular volume change (dV/dt) still present in ischemic single ferret lungs after 20 min of P(v) = 30 Torr and 2) developed an equation for sigma that allowed a finite dV/dt. In 25 lungs, we estimated the dV/dt after 20 min at P(v) = 30 Torr by subtracting from the rate of lung weight gain (W(L)). The relationship between (0.15 +/- 0.02 ml/min) and W(L) (0.24 +/- 0.02 g/min) was significant (R = 0.66, P < 0.001), but the slope was <1 (0.41 +/- 0.10, P < 0.05). dV/dt (0.10 +/- 0.02 ml/min) was similar in magnitude to at 20 min. The modified equation for sigma revealed that a finite dV/dt caused the original sigma measurement to underestimate true sigma. A low sigma, high, high baseline Hct, and long filtration time enhanced the error. The error was small, however, and could be minimized by adjusting experimental parameters.     

Effect of ajmaline on action potential and ionic currents in rat ventricular myocytes

The effect of ajmaline on action potential (AP) and ionic current components has been investigated in right ventricular myocytes of rat at room temperature using the whole cell patch clamp technique. Ajmaline decreased the upstroke velocity ((dV/dt)max) of AP and the AP amplitude, increased the AP duration measured at 50 and 90% repolarization, and reversibly inhibited most components of membrane ionic current in a concentration-dependent manner. The following values of IC50 and of the Hill coefficient (nH) resulted from approximation of the measured data by the Hill formula: for fast sodium current (INa) IC50=27.8+/-1.14 micromol/l and nH=1.27+/-0.25 at holding potential -75 mV, IC50=47.2+/-1.16 micromol/l and nH=1.16+/-0.21 at holding potential -120 mV; for L-type calcium current (ICa-L) IC50=70.8+/-0.09 micromol/l and n(H)=0.99+/-0.09; for transient outward potassium current (Ito) IC50=25.9+/-2.91 micromol/l and nH=1.07+/-0.15; for ATP-sensitive potassium current (IK(ATP)) IC50=13.3+/-1.1 micromol/l and nH=1.16+/-0.15. The current measured at the end of 300 ms depolarizing impulse was composed of an ajmaline-insensitive component and a component inhibited with IC50=61.0+/-1.1 micromol/l and nH=0.91+/-0.08. At hyperpolarizing voltages, ajmaline at high concentration of 300 micromol/l reduced the inward moiety of time-independent potassium current (IK1) by 36%. The results indicate that the inhibition of INa causes both the decreased rate of rise of depolarizing phase and the lowered amplitude of AP. The inhibition of Ito is responsible for the ajmaline-induced AP prolongation.     

A mathematical model of action potential heterogeneity in adult rat left ventricular myocytes.

Mathematical models were developed to reconstruct the action potentials (AP) recorded in epicardial and endocardial myocytes isolated from the adult rat left ventricle. The main goal was to obtain additional insight into the ionic mechanisms responsible for the transmural AP heterogeneity. The simulation results support the hypothesis that the smaller density and the slower reactivation kinetics of the Ca(2+)-independent transient outward K(+) current (I(t)) in the endocardial myocytes can account for the longer action potential duration (APD), and more prominent rate dependence in that cell type. The larger density of the Na(+) current (I(Na)) in the endocardial myocytes results in a faster upstroke (dV/dt(max)). This, in addition to the smaller magnitude of I(t), is responsible for the larger peak overshoot of the simulated endocardial AP. The prolonged APD in the endocardial cell also leads to an enhanced amplitude of the sustained K(+) current (I(ss)), and a larger influx of Ca(2+) ions via the L-type Ca(2+) current (I(CaL)). The latter results in an increased sarcoplasmic reticulum (SR) load, which is mainly responsible for the higher peak systolic value of the Ca(2+) transient [Ca(2+)](i), and the resultant increase in the Na(+)-Ca(2+) exchanger (I(NaCa)) activity, associated with the simulated endocardial AP. In combination, these calculations provide novel, quantitative insights into the repolarization process and its naturally occurring transmural variations in the rat left ventricle.     

Interstitial potential during propagation in bathed ventricular muscle.

Theoretical simulations have suggested that interstitial potential (Vis) during action potential propagation affects measurements of the transmembrane action potential in bathed ventricular muscle. To evaluate the Vis experimentally, we obtained Vis and intracellular action potential (Vic) recordings at various depths in paced guinea pig papillary muscles bathed in oxygenated Tyrode's solution. The peak-to-peak amplitude and the maximum dV/dt (dV/dtmax) of the intrinsic downward deflection of the Vis recordings were determined. The transmembrane action potential (TM) was obtained by subtracting each Vis from the corresponding Vic recording, and measurements for the phase zero depolarization and action potential foot of the Vic were compared with the measurements for the TM. At penetration depths of approximately 54 microns, the amplitude and dV/dtmax of the Vis were 13 mV and -38 V/s. When the depth was increased to 200 microns, these parameters increased to 24 mV and -59 V/s (P less than 0.005), and when the depth was further increased to 390 microns, the parameters decreased to 16 mV and -38 V/s. Because of the Vis at the various depths, the Vic underestimated dV/dtmax of phase zero of the TM by 20-31%, which would reduce estimates of Na+ current obtained from dV/dt. Also, the Vic overestimated the time constant of the 2-8 mV foot of the action potential by 48-82%, which would reduce estimates of the "effective" membrane capacitance by 33-45%. These influences of the Vis on measurements may affect results of quantitative studies of the ventricular action potential.     

Adaptability of the Gompertz equation to the growth kinetics of a transplantable experimental tumor

We have carried out a study on the growth kinetics of a solid rat reticulosarcoma, by making use of the Gompertz equation. This approach is not sufficiently valid for the groups as a whole, but furnishes useful information when applied to individual tumors. In fact the values for relative (1/V dV/dt) and absolute (dV/dt) velocities calculated for individual tumors by making use of this equation, exhibit greater significance and consistency with respect to tumor-host integration.     

Effect of local anaesthetics (mesocain) on membrane properties of cat papillary muscle

In 28 experiments on cat papillary muscles the effect of mesocain (generically related to lidocaine) was studied on transmembrane currents (rapid inward INa, slow inward Isi, outward Io), on the configuration and (dV/dt)max of the action potential, on the refractory period and on isometric tension. The experiments were performed using either voltage clamp method (double sucrose gap) or microelectrode technique. All three transmembrane currents are inhibited by mesocain in a dose-dependent manner. The effect becomes measurable at 10(-6) mol/1 on INa, at 10(-5) mol/1 on Isi and at 5 X 10(-5) mol/1 on Il. INa is blocked at 10(-3) mol/1 concentration. These changes correlate with the measured alterations of action potentials: i.e. a decreased (dV/dt) max and overshoot, lower voltage and shortening of the plateau phase, slower rate of late repolarizaion. The negative inotropic effect appeared with the same treshold concentration as Isi; at higher concentrations, however, this effect was relatively much greater. The recovery of excitability measured by the interval-dependence of (dV/dt) max was prolonged 5 times on the average by mesocain at 10(-4) mol/1 and the effective refractory period was delayed beyond complete repolarization. It is concluded that the main effect of mesocain also involves a delayed kinetics of recovery from inactivation of the Na carrying system.     

Mechanism of outercellular [K+] in generation of pacemaker action potentials in sinoatrial valve of the rabbit

In a control solution (solution I; 3 mM K+, 35 degrees C) the amplitude of APs of cells in the valve centre was 81 +/- 6 mV (Mean +/- SEM), the maximal upstroke velocity (dV/dtmax) was 19 +/- 4 V/s, velocity slow diastolic depolarization (DD) - 65 +/- 8 mV/s, the rate of spontaneous AP generation was 135 +/- 14 bpm. Hypo K+ (50 %) solution (solution II) decreased slow DD by - 22 % and dV/dtmax by -58 % and the rate of AP generation by 15 % compared to the control solution. In saline solution, decrease of Emax from -68 to -45 mV and four-fold decrease of slow DD and dV/dtmax were registered at the 8th of exposure. After that the Emax noise and origin of early (EADs) and delay (DADs) afterdepolarizations were observed. Comparative analysis of the main AP parameters of SA valve latent pacemaker cells in solution III (without K+) and solution IV (without KC1 and CaCl2) exposure demonstrated that changes of this parameters in solution IV were less then in solution III. It is interesting that in solution IV exposure the phase of the early repolarization (phase 1) was differentiated, dV/dtmax was increased by 21%. The frequency of AP generation decreased by 18 % as in solution with 50% K+. At the same time, EADs were not registered. It seems that the decreasing of the transsarcolemal gradient of K+ depolarized Emax despite Nernst equation. At the same time permeability was decreased for K+ and Na+ ions. That could involve Ca2+ overload and origin of EADs and DADs.     

Alteration of the action potential of tissue cultured neuronal cells by growth in the presence of a polyunsaturated fatty acid

The effects of alterations in membrane phospholipid fatty acid composition on the excitability of neuroblastoma × glioma hybrid cells, clone NG108-15, were examined using intracellular recording techniques. Cells were grown in the presence of arachidonate (20:4) added to the culture medium as a complex with bovine serum albumin. Exposure of the cells to 20:4 for 3–21 days produced a 40% decrease in the maximum rate of rise of the action potential (dV/dt) with a small change in its amplitude. The resting membrane potential and passive properties of the cells were unaffected. An effect of 20:4 was not observed until 24 hr after treatment and increased over the next 2 days. The phospholipid content of 20:4 and its metabolite 22:4 increased from 6.9% to 25.3% of total fatty acids during approximately the same time span. It is concluded that the action potential dV/dt can be altered by changes in membrane lipid composition.     

AP2 clathrin adaptor complex, but not AP1, controls the access of the major histocompatibility complex (MHC) class II to endosomes

Newly synthesized MHC II alpha- and beta-chains associated with the invariant chain chaperone (Ii) enter the endocytic pathway for Ii degradation and loading with peptides before transport to the cell surface. It is unclear how alphabetaIi complexes are sorted from the Golgi apparatus and directed to endosomes. However, indirect evidence tends to support direct transport involving the AP1 clathrin adaptor complex. Surprisingly, we show here that knocking down the production of AP1 by RNA interference did not affect the trafficking of alphabetaIi complexes. In contrast, AP2 depletion led to a large increase in surface levels of alphabetaIi complexes, inhibited their rapid internalization, and strongly delayed the appearance of mature MHC II in intracellular compartments. Thus, in the cell systems studied here, rapid internalization of alphabetaIi complexes via an AP2-dependent pathway represents a key step for MHC II delivery to endosomes and lysosomes.     

Re-evaluation of the action potential upstroke velocity as a measure of the Na+ current in cardiac myocytes at physiological conditions

Background

The SCN5A encoded sodium current (I_Na) generates the action potential (AP) upstroke and is a major determinant of AP characteristics and AP propagation in cardiac myocytes. Unfortunately, in cardiac myocytes, investigation of kinetic properties of I_Na with near-physiological ion concentrations and temperature is technically challenging due to the large amplitude and rapidly activating nature of I_Na, which may seriously hamper the quality of voltage control over the membrane. We hypothesized that the alternating voltage clamp-current clamp (VC/CC) technique might provide an alternative to traditional voltage clamp (VC) technique for the determination of I_Na properties under physiological conditions.

Principal Findings

We studied I_Na under close-to-physiological conditions by VC technique in SCN5A cDNA-transfected HEK cells or by alternating VC/CC technique in both SCN5A cDNA-transfected HEK cells and rabbit left ventricular myocytes. In these experiments, peak I_Na during a depolarizing VC step or maximal upstroke velocity, dV/dt_max, during VC/CC served as an indicator of available I_Na. In HEK cells, biophysical properties of I_Na, including current density, voltage dependent (in)activation, development of inactivation, and recovery from inactivation, were highly similar in VC and VC/CC experiments. As an application of the VC/CC technique we studied I_Na in left ventricular myocytes isolated from control or failing rabbit hearts.

Conclusions

Our results demonstrate that the alternating VC/CC technique is a valuable experimental tool for I_Na measurements under close-to-physiological conditions in cardiac myocytes.     

Contribution of Starling and lymphatic flows to pleural liquid exchanges in anesthetized rabbits

We studied the time course of volume and protein reabsorption of a 2-ml hydrothorax using whole (WP) or diluted (DP) homologous plasma injected into the right pleural cavity in anesthetized spontaneously breathing supine rabbits. Animals were killed at 5 (WP, n = 4; DP, n = 3), 36 (WP, n = 3; DP, n = 4), 55 (WP, n = 4), 90 (WP, n = 8; DP, n = 4), and 150 (WP, n = 4; DP, n = 5) min after the injection. The volume and protein content of the pleural liquid in control conditions (n = 12) amounted to 0.35 +/- 0.015 (SE) ml/kg and 1.8 +/- 0.27 g/100 ml, respectively, which are not significantly different at 90 min (n = 7). Pleural liquid volume decreased at a similar rate during WP or DP reabsorption according to the equation V = 0.84 +/- 0.05 X e-0.02t, with net reabsorptive flow expressed as dV/dt. The globulin quantity (Q) of the pleural liquid for WP and DP, respectively, decreased according to the equations Qwp = 1 + 1.5 X e-0.04t and Qdp = 0.7 + 0.6 X e-0.03t. Assuming a major lymphatic globulin clearance and no filtration into the cavity, we obtained lymph flow using the equation VL = dQ/dt X l/C where dQ/dt is calculated from the equations for Qwp and Qdp and C represents globulin concentration. The Starling flow (Vs) was then calculated by the equation Vs = dV/dt-VL. With increasing time, lymph flow was found to decrease progressively and was not significantly different from net flow with DP, which implied a Starling flow value of zero. During WP reabsorption, lymph flow initially exceeded the net flow, with the difference disappearing at approximately 60 min; accordingly, Starling filtration flow decreased progressively, becoming zero at the same time.     

Complexes of two cohorts of CLIP peptides and HLA-DQ2 of the autoimmune DR3-DQ2 haplotype are poor substrates for HLA-DM

Atypical invariant chain (Ii) CLIP fragments (CLIP2) have been found in association with HLA-DQ2 (DQ2) purified from cell lysates. We mapped the binding register of CLIP2 (Ii 96-104) to DQ2 and found proline at the P1 position, in contrast to the canonical CLIP1 (Ii 83-101) register with methionine at P1. CLIP1/2 peptides are the predominant peptide species, even for DQ2 from HLA-DM (DM)-expressing cells. We hypothesized that DQ2-CLIP1/2 might be poor substrates for DM. We measured DM-mediated exchange of CLIP and other peptides for high-affinity indicator peptides and found it is inefficient for DQ2. DM-DQ-binding and DM chaperone effects on conformation and levels of DQ are also reduced for DQ2, compared with DQ1. We suggest that the unusual interaction of DQ2 with Ii and DM may provide a basis for the known disease associations of DQ2.     

Action of acetylcholine on the mammalian auricle influenced by verapamil

The action of acetylcholine (ACh) and verapamil (VePa) on the action potential (V(t)), phase plane trajectories of V(t) (dV/dt--V(t) -- plot) and isotonic contractions were investigated using an isolated vegal innervated preparation from rabbit atrium (method I) and investigating action potentials from atrial trabeculae by means a modified sucrose gap technique (method II). If the VePa-concentration increases to 4 mg/1 the duration of the action potential decreases at 20 and 90% repolarization (driving frequencies 2 s-1). In the VePa-solutions phase plane trajectories of the action potential did not change significantly. ACh application favours the disappearance of a region in the repolarization phase plane plot showing anomalous rectification (d(--dV/dt)/dV less than 0) both by control conditions and verapamil. The electrotropic ACh-and vagal effects will be unchanged by verapamil. The inotropic ACh-and vegal action (method I) increases by VePa (2 mg/1). The action of ACh and verapamil will be analysed using a mathematical model for reconstructing the repolarization phase of mammalian atrial myocardium action potentials.     

Multiple equilibria and exotic behaviour in excitable membranes

The excitation equation for an excitable membrane dV/dt=F(V) may have multiple equilibria where F(V)=0, and these may be stable or unstable. We demonstrate multiple equilibria in the Hodgkin-Huxley equations when either g_K or [Ca²⁺]₀ is lowered in the presence of a hyperpolarising current density. Under these conditions molluscan somata exhibit exotic behaviours-endogenous paroxysmal depolarising shifts and complex multiple spikes reminiscent of the normal complex activity of some mammalian central neurones. Complex discharge waveforms can be an expression of membrane (differential) properties, rather than electrotonic, geometric (partial differential) behaviour.     

Heterogeneous connexin43 expression produces electrophysiological heterogeneities across ventricular wall

Recently we found that electrophysiological (EP) heterogeneities between subepicardial and midmyocardial cells can form a substrate for reentrant ventricular arrhythmias. However, cell-to-cell coupling through gap junctions is expected to attenuate transmural heterogeneities between cell types spanning the ventricular wall. Because connexin43 (Cx43) is the principal ventricular gap junction protein, we hypothesized that transmural EP heterogeneities are in part produced by heterogeneous Cx43 expression across the ventricular wall. The left ventricles of eight dogs were sectioned to expose the transmural surface. To determine whether heterogeneous Cx43 expression influenced EP function, high-resolution transmural optical mapping of the arterially perfused canine wedge preparation was used to measure transmural conduction velocity (thetaTM), dV/dt(max), transmural space constant (lambdaTM), and transmural gradients of action potential duration (APD). Relative Cx43 expression, quantified by confocal immunofluorescence, was significantly lower (by 24 +/- 17%; P < 0.05) in subepicardial compared with deeper layers. Importantly, reduced subepicardial Cx43 was associated with transmural heterogeneities of EP function evidenced by selectively reduced subepicardial thetaTM (by 18 +/- 9%; P < 0.05) compared with deeper layers. In subepicardial regions, dV/dt(max) was fastest (by 19 +/- 15%) and lambdaTM was smallest (by 18.1 +/- 2%), which suggests that conduction slowing was attributable to localized uncoupling rather than reduced excitability. The maximum transmural APD gradients occurred in the same regions where Cx43 expression was lowest; this suggests that Cx43 expression patterns served to maintain APD gradients across the transmural wall. These data demonstrate that heterogeneous Cx43 expression is closely associated with functionally significant EP heterogeneities across the transmural wall. Therefore, Cx43 expression patterns can potentially contribute to arrhythmic substrates that are dependent on transmural electrophysiological heterogeneities.     

Expression and function of transgenic HLA-DQ molecules and lymphocyte development in mice lacking invariant chain

Invariant chain (Ii) is a non-MHC-encoded molecule, which plays an accessory role in the proper assembly/expression of functional MHC class II molecules and there by plays an important role in Ag processing/presentation. The phenotype of mice lacking Ii depends on the allotype of the MHC class II molecule. In some mice strains, Ii deficiency results in reduction in expression of class II molecules accompanied by defective CD4(+) T cell development. Responses to conventional Ags/superantigens are also compromised. In this study, we describe for the first time the functionality of human class II molecules, HLA-DQ6 and HLA-DQ8, in transgenic mice lacking Ii. HLA transgenic Ii(-/-) mice expressed very low levels of surface DQ6 and DQ8 accompanied by severe reduction in CD4(+) T cells both in the thymus and periphery. In vitro proliferation and cytokine production to an exogenous superantigen, staphylococcal enterotoxin B (SEB) was diminished in HLA-transgenic Ii(-/-) mice. However, SEB-induced in vivo expansion of CD8(+) T cells expressing TCR Vbeta8 family in DQ8.Ii(-/-) mice was comparable with that of DQ8.Ii(+/+) mice. Systemic IFN-gamma production following in vivo challenge with SEB was reduced in DQ8.Ii(-/-) mice and were also protected from SEB-induced toxic shock. Although the T cell response to a known peptide Ag was diminished in DQ8.Ii(-/-) mice, DQ8.Ii(-/-) APCs were capable of presenting that peptide to primed T cells from wild-type DQ8 mice as well as to a specific T cell hybridoma. Differentiation of mature B cells was also affected to a certain extent in DQ8.Ii(-/-) mice.     

Phase Plane Trajectories of the Muscle Spike Potential

To facilitate a study of the transmembrane action current, the striated muscle spike potential was recorded against its first time derivative. The specialized recording methods are described, as well as several mathematical transformations between a coordinate system in V, t, and the present coordinate system in V, dV/dt. The particular properties of the present recording method permitted an estimation for the “sodium” potential in muscle fibers at +39 mv. The maximum membrane conductance during spike production is in the order of 150 to 200 mmhos/cm². The changes in the shape of the recorded response indicate that the ionic currents and membrane conductances are reduced by Tris buffer or hypertonic Ringer's fluid. However, no marked changes in the properties of active membrane were observed when chloride ion was replaced by sulfate.     

The Role of the Contractile Vacuole in the Osmoregulation of Tetrahymena pyriformis*

The relationship of cell size and contractile vacuole efflux to osmotic stress was studied in Tetrahymena pyriformis strain W, after transfer into fresh solutions iso- or hypoosmotic to the growth medium. Microscopic measurements of the cell and contractile vacuole dimensions, made with an image-sharing ocular at 27 C, allowed the calculation of the cell size and shape and the vacuolar efflux rate which provide a measure of osmoregulation. The contractile vacuole cycles have no homeostatic oscillations. In 0.03–0.10 osmolar solutions, the cell size and shape are constant while the vacuolar efflux rate has an inverse linear dependence upon extracellular osmolarity. Regression analyses indicate that for cells with systole faster than 0.1 sec (the major part of the population), it is only the final diastolic volume of the contractile vacuole that is related to osmotic stress while the frequency of systole is independent of osmotic stress and has a constant period of 7.7 ± 0.2 sec. Therefore, osmotic stress upon Tetrahymena is regulated by a corresponding change in the filling rate of its contractile vacuole to allow an unaltered cell size and shape. Kinetic measurements of vacuoles during diastole fit the model (dV/dt = K_1-K₂A), where (dV/dt) is the vacuolar filling rate and (A) is the vacuolar surface area. This dependence of vacuolar volume upon its surface area may be ascribed either to elastic components of the vacuolar membrane or to an increasing leakiness of this membrane during diastole. Mitochondrial inhibitors were used to observe the energy requirements of vacuolar operation and of intracellular secretion of water.     

The effects of exposure to exogenous fatty acids and membrane fatty acid modification on the electrical properties of NG108-15 cells

The role of membrane lipid composition in determining the electrical properties of neuronal cells was investigated by altering the available fatty acids in the growth medium of cultured neuroblastoma X glioma hybrid cells, clone NG108-15. Growth of the cells for several days in the presence of polyunsaturated fatty acids (linoleic, linolenic, and arachidonic) caused a pronounced decrease in the Na+ action-potential rate of rise (dV/dt) and smaller decreases in the amplitude, measured by intracellular recording. Oleic acid had no effect on the action potentials generated by the cells. In contrast, a saturated fatty acid (palmitate) and a trans monounsaturated fatty acid (elaidate) caused increases in both the rate of rise and the amplitude. No changes in the resting membrane potentials or Ca2+ action potentials of fatty acid-treated cells were observed. The membrane capacitance and time constant were not altered by exposure to arachidonate, oleate, or elaidate, whereas arachidonate caused a small increase in membrane resistance. Examination of the membrane phospholipid fatty acid composition of cells grown with various fatty acids revealed no consistent alterations which could explain these results. To examine the mechanism for arachidonate-induced decreases in dV/dt, the binding of 3H-saxitoxin (known to interact with voltage-sensitive Na+) channels was measured. Membranes from cells grown with arachidonate contained fewer saxitoxin binding sites, suggesting fewer Na+ channels in these cells. We conclude that conditions which lead to major changes in the membrane fatty acid composition have no effect on the resting membrane potential, membrane capacitance, time constant, or Ca2+ action potentials in NG108-15 cells. Membrane resistance also does not appear to be very sensitive to membrane fatty acid composition. However, changes in the availability of fatty acids and/or changes in the subsequent membrane fatty acid composition lead to altered Na+ action potentials. The primary mechanism for this alteration appears to be through changes in the number of Na+ channels in the cells.     

The MHC class II-associated invariant chain interacts with the neonatal Fc gamma receptor and modulates its trafficking to endosomal/lysosomal compartments

The neonatal Fc receptor for IgG (FcRn) transfers maternal IgG to the offspring and protects IgG from degradation. The FcRn resides in an acidic intracellular compartment, allowing it to bind IgG. In this study, we found the association of FcRn and invariant chain (Ii). The interaction was initiated within the endoplasmic reticulum by Ii binding to either the FcRn H chain alone or FcRn H chain-beta(2)-microglobulin complex and appeared to be maintained throughout the endocytic pathway. The CLIP in Ii was not required for FcRn-Ii association. The interaction was also detected in IFN-gamma-treated THP-1, epithelial and endothelial cells, and immature mouse DCs. A truncated FcRn without the cytoplasmic tail was unable to traffic to early endosomes; however, its location in early endosomes was restored by Ii expression. FcRn was also detected in the late endosome/lysosome only in the presence of Ii or on exposure to IFN-gamma. In immature human or mouse DCs, FcRn was barely detected in the late endosome/lysosome in the absence of Ii. Furthermore, the cytoplasmic tail of Ii conferred tailless FcRn to route to both the early endosome and late endosome/lysosome in a hybrid molecule. Because the FcRn is expressed in macrophages and DCs or epithelial and endothelial cells where Ii is induced under inflammation and infection, these results reveal the complexity of FcRn trafficking in which Ii is capable of expanding the boundary of FcRn trafficking. Taken together, the intracellular trafficking of FcRn is regulated by its intrinsic sorting information and/or an interaction with Ii chain.