Electrical dimension of the nuclear envelope.

Eukaryotic chromosomes are confined to the nucleus, which is separated from the rest of the cell by two concentric membranes known as the nuclear envelope (NE). The NE is punctuated by holes known as nuclear pore complexes (NPCs), which provide the main pathway for transport of cellular material across the nuclear-cytoplasmic boundary. The single NPC is a complicated octameric structure containing more than 100 proteins called nucleoporins. NPCs function as transport machineries for inorganic ions and macromolecules. The most prominent feature of an individual NPC is a large central channel, ~7 nm in width and 50 nm in length. NPCs exhibit high morphological and functional plasticity, adjusting shape to function. Macromolecules ranging from 1 to >100 kDa travel through the central channel into (and out of) the nucleoplasm. Inorganic ions have additional pathways for communication between cytosol and nucleus. NE can turn from a simple sieve that separates two compartments by a given pore size to a smart barrier that adjusts its permeabiltiy to the metabolic demands of the cell. Early microelectrode work characterizes the NE as a membrane barrier of highly variable permeability, indicating that NPCs are under regulatory control. Electrical voltage across the NE is explained as the result of electrical charge separation due to selective barrier permeability and unequal distribution of charged macromolecules across the NE. Patch-clamp work discovers NE ion channel activity associated with NPC function. From comparison of early microelectrode work with patch-clamp data and late results obtained by the nuclear hourglass technique, it is concluded that NPCs are well-controlled supramolecular structures that mediate transport of macromolecules and small ions by separate physical pathways, the large central channel and the small peripheral channels, respectively. Electrical properties of the two pathways are still unclear but could have great impact on the understanding of signal transfer across NE and gene expression.

Dendrimer-assisted patch-clamp sizing of nuclear pores.

Macromolecular translocation (MMT) across the nuclear envelope (NE) occurs exclusively through the nuclear pore complex (NPC). Therefore, the diameter of the NPC aqueous/electrolytic channel (NPCC) is important for cellular structure and function. The NPCC diameter was previously determined to be approximately equal to 10 nm with electron microscopy (EM) using the translocation of colloidal gold particles. Here we present patch-clamp and fluorescence microscopy data from adult cardiomyocyte nuclei that demonstrate the use of patch-clamp for assessing NPCC diameter. Fluorescence microscopy with B-phycoerythrin (BPE, 240 kDa) conjugated to a nuclear localization signal (NLS) demonstrated that these nuclei were competent for NPC-mediated MMT (NPC-MMT). Furthermore, when exposed to an appropriate cell lysate, the nuclei expressed enhanced green fluorescence protein (EGFP) after 5-10 h of incubation with the plasmid for this protein (pEGFP, 3.1 MDa). Nucleus-attached patch-clamp showed that colloidal gold particles were not useful probes; they modified NPCC gating. As a result of this finding, we searched for an inert class of particles that could be used without irreversibly affecting NPCC gating and found that fluorescently labeled Starburst dendrimers, a distinct class of polymers, were useful. Our patch-clamp and fluorescence microscopy data with calibrated dendrimers indicate that the cardiomyocyte NPCC diameter varies between 8 and 9 nm. These studies open a new direction in the investigation of live, continuous NPC dynamics under physiological conditions.

Calcium, ATP and nuclear pore channel gating.

Nuclear envelope (NE) cisternal Ca2+ and cytosolic ATP are required for nuclear-pore-complex-(NPC-) mediated transport of DNAs, RNAs, transcription factors and other large molecules. Isolated cardiomyocyte nuclei, capable of macromolecular transport (MMT), have intrinsic NPC ion channel behavior. The large ion conductance (gamma) activity of the NPC channel (NPCC) is blocked by the NPC monoclonal antibody mAb414, known to block MMT, and is also silenced during periods of MMT. In cardiomyocytes, neither cytosolic Ca2+ nor ATP alone directly affects NPCC gating. To test the role of Ca2+ and ATP in NPCC activity, we carried out the present patch-clamp study with the pipette attached to the outer NE membrane of nuclei isolated from cultured Dunning G prostate cancer cells. Our investigations demonstrate that in these isolated nuclei neither cytosolic Ca2+ nor ATP alone directly affects NPCC gating. However, when simultaneously applied to the bath and pipette, they transiently silence NPCC activity through stimulation of MMT by raising the Ca2+ concentration in the NE cisterna ([Ca2+]NE). Our fluorescence microscopy observations with nuclear-targeted macromolecular fluorochromes (B-phycoerythrin and plasmid for the enhanced green fluorescence protein EGFP, pEGFP-C1) and with FITC-labeled RNA support the view that channel silence accompanies MMT. Repeated Ca2+ loading of the NE with Ca2+ and ATP, after unloading with 1-5 microM inositol 1,4,5-trisphosphate (IP3), thapsigargin (TSG) or 5 mM BAPTA or EGTA, failed to affect channel gating. This result indicates that other factors are involved in this phenomenon and that they are exhausted during the first cycle of NE Ca2+ loading/unloading--in agreement with current theories of NPC-mediated MMT. The results explain how Ca2+ and IP3 waves may convert the NE into an effective Ca2+ barrier and, consequently, affect the regulation of gene activity and expression through their feedback on MMT and NPCC gating. Thus, [Ca2+]NE regulation by intracellular messengers is an effective mechanism for synchronizing gene activity and expression to the cellular rhythm.

Patch-clamp detection of macromolecular translocation along nuclear pores.

The present paper reviews the application of patch-clamp principles to the detection and measurement of macromolecular translocation along the nuclear pores. We demonstrate that the tight-seal 'gigaseal' between the pipette tip and the nuclear membrane is possible in the presence of fully operational nuclear pores. We show that the ability to form a gigaseal in nucleus-attached configurations does not mean that only the activity of channels from the outer membrane of the nuclear envelope can be detected. Instead, we show that, in the presence of fully operational nuclear pores, it is likely that the large-conductance ion channel activity recorded derives from the nuclear pores. We conclude the technical section with the suggestion that the best way to demonstrate that the nuclear pores are responsible for ion channel activity is by showing with fluorescence microscopy the nuclear translocation of ions and small molecules and the exclusion of the same from the cisterna enclosed by the two membranes of the envelope. Since transcription factors and mRNAs, two major groups of nuclear macromolecules, use nuclear pores to enter and exit the nucleus and play essential roles in the control of gene activity and expression, this review should be useful to cell and molecular biologists interested in understanding how patch-clamp can be used to quantitate the translocation of such macromolecules into and out of the nucleus.

Patch-clamp detection of macromolecular translation along nuclear pores

The present paper reviews the application of patch-clamp principles to the detection and measurement of macromolecular translocation along the nuclear pores. We demonstrate that the tight-seal `gigaseal' between the pipette tip and the nuclear membrane is possible in the presence of fully operational nuclear pores. We show that the ability to form a gigaseal in nucleus-attached configurations does not mean that only the activity of channels from the outer membrane of the nuclear envelope can be detected. Instead, we show that, in the presence of fully operational nuclear pores, it is likely that the large-conductance ion channel activity recorded derives from the nuclear pores. We conclude the technical section with the suggestion that the best way to demonstrate that the nuclear pores are responsible for ion channel activity is by showing with fluorescence microscopy the nuclear translocation of ions and small molecules and the exclusion of the same from the cisterna enclosed by the two membranes of the envelope. Since transcription factors and mRNAs, two major groups of nuclear macromolecules, use nuclear pores to enter and exit the nucleus and play essential roles in the control of gene activity and expression, this review should be useful to cell and molecular biologists interested in understanding how patch-clamp can be used to quantitate the translocation of such macromolecules into and out of the nucleus.

Atomic force microscopy visualizes ATP-dependent dissociation of multimeric TATA-binding protein before translocation into the cell nucleus.

The TATA-binding protein (TBP) is a universal transcription factor which plays an essential role in eukaryotic gene expression. As a karyophilic molecule, this cytosolic protein reaches its DNA-binding site through the transport channel of the nuclear pore complex. As occurs with other major cellular proteins, TBP forms multimers in solution, which is a limiting factor for nuclear translocation. While studying the nuclear translocation of TBP, we detected ATP-dependent multimerization of TBP with atomic force microscopy. In physiological solutions containing ATP, 14-molecule multimers dissociated into four-molecule multimers with a half-maximum dissociation constant of 10 microM. Electrophysiological experiments using isolated cell nuclei of cultured kidney cells revealed that TBP translocates into the cell nucleus only in the presence of ATP. When ATP was replaced with its slowly hydrolysing analogue, ATP[gamma-S] [i.e. adenosine 5'-o-(3-thiotriphosphate)], the aggregates remained intact and nuclear translocation was not possible. Taken together, our investigations suggest that TBP exhibits ATPase activity similar to that observed in relation to molecular chaperons. This activity secures physiological translocation of the transcription factor into the nucleus.

Induction of bimodal programmed cell death in malignant cells by the derivative Ukrain (NSC-631570).

Selective induction of malignant cell death is one of the major goals of effective and safe chemotherapy. Recent developments in the understanding of programmed cell death (PCD) or apoptosis are expected to provide new leads for a safer chemotherapy. The authors investigated whether the semisynthetic alkaloid thiophosphoric acid derivative Ukrain (NSC-631570) could induce PCD or apoptosis in human K562 leukaemia cells. Results showed that Ukrain induced two distinct modalities of cell death programmes. One modality corresponded morphologically to classical apoptosis or PCD characterized by blebbing and shedding of membrane vesicles with concomitant 51Cr release; however, the Ukrain-induced apoptosis was not associated with the characteristic nuclear DNA fragmentation. Higher concentrations of Ukrain induced a second cell death programme characterized by cell surface blister formation, high specific 51Cr release and extensive DNA polyploidy. These two cell death programmes are distinct from each other in that they are interphased by a silent period characterized by normal cell morphology and reduced specific 51Cr release.

Patch clamp detection of transcription factor translocation along the nuclear pore complex channel.

Transcription factors (TFs) are cytoplasmic proteins that play an essential role in gene expression. These proteins form multimers and this phenomenon is thought to be one of the mechanisms that regulate transcription. TF molecules reach their DNA binding sites through the large central channel of the nuclear pore complex (NPC). However, the NPC channel is known to restrict the translocation of molecules > or = 20-70 kD. Therefore, during their translocation, TF molecules and/or their multimers may plug the NPC channel and thus, interrupt ion flow through the channel, with a concomitant reduction in the ion conductance of the channel (gamma). Here we show with patch clamp that gamma is reduced during translocation of three major TFs: c-Jun (40 kD), NF-kappa B (approximately equal to 50 kD), and SP1 (approximately equal to 100 kD). Within a minute, femtomolar concentrations of these proteins reduced gamma suggesting a purely mechanical interaction between single TF molecules and the inner wall of the NPC channel. NPCs remained plugged for 0.5-3 hr in the absence of ATP but when ATP was added, channel plugging was shortened to < 5 min. After unplugging, channel closures were rarely observed and the number of functional channels increased. The transcription factors also stabilized the NPCs as shown by the extended duration of the preparations which allowed recordings for up to 72 hr. These observations are the first direct demonstration of the important role of NPCs in mediating nuclear translocation of TFs and, therefore, in forming part of the mechanisms regulating gene expression.(ABSTRACT TRUNCATED AT 250 WORDS)

The ion channel behavior of the nuclear pore complex.

Macromolecule-conducting pores have been recently recognized as a distinct class of ion channels. The poor role of macromolecules as electrical charge carriers can be used to detect their movement along electrolyte-filled pores. Because of their negligible contribution to electrical ion currents, translocating macromolecules reduce the net conductivity of the medium inside the pore, thus decreasing the measured pore ion conductance. In the extreme case, a large translocating macromolecule can interrupt ion flow along the pore lumen, reflected as a negligible pore conductance. Therefore, ion conductance serves as a measurement of macromolecular transport, with lesser values indicating greater macromolecular translocation (in size and/or number). Such is the principle of operation of the widely used Coulter counter, an instrument for counting and sizing particles. It has long been known that macromolecules translocate across the central channel of nuclear pore complexes (NPCs). Recently, large conductance ion channel activity (100-1000 pS) was recorded from the nuclear envelope (NE) of various preparations and it was suggested that NPCs may be the source of this activity. Despite its significance to understanding the regulation of transcription, replication, mRNA export, and thus gene expression of normal and pathological states, no report has appeared demonstrating that this channel activity corresponds to ion flow along the central channel of the NPC. Here we present such a demonstration in adult mouse cardiac myocyte nuclei. In agreement with concepts introduced for macromolecule-conducting channels, our patch clamp experiments showed that ion conductance is reduced, and thus that ion flow is restricted during translocation of macromolecules containing nuclear targeting signals. Ion flow was blocked by mAb414, a monoclonal antibody raised against a major NPC glycoprotein and known to localize on the NPC channel where it blocks macromolecular transport. These results also establish patch clamp as a useful technique for the measurement of macromolecular translocation along the large central channel of the NPC and provide a basis for the design of future investigations of nuclear signaling for control of gene activity, mRNA export for gene expression, as well as other processes subservient to NPC-mediated nucleocytoplasmic exchange.

Patch clamp and atomic force microscopy demonstrate TATA-binding protein (TBP) interactions with the nuclear pore complex.

The universal TATA-binding protein, TBP, is an essential component of the multiprotein complex known as transcription factor IID (TFIID). This complex, which consists of TBP and TBP-associated factors (TAFs), is essential for RNA polymerase II-mediated transcription. The molecular size of human TBP (37.7 kD) is close to the passive diffusion limit along the transport channel of the nuclear pore complex (NPC). Therefore, the possibility exists that NPCs restrict TBP translocation to the nuclear interior. Here we show for the first time, with patch-clamp and atomic force microscopy (AFM), that NPCs regulate TBP movement into the nucleus and that TBP (10(-15)-10(-10)M) is capable of modifying NPC structure and function. The translocation of TBP was ATP-dependent and could be detected as a transient plugging of the NPC channels, with a concomitant transient reduction in single NPC channel conductance, gamma, to a negligible value. NPC unplugging was accompanied by permanent channel opening at concentrations greater than 250 pM. AFM images demonstrated that the TBP molecules attached to and accumulated on the NPC cytosolic side. NPC channel activity could be recorded for more than 48 hr. These observations suggest that three novel functions of TBP are: to stabilize NPC, to force the NPC channels into an open state, and to increase the number of functional channels. Since TBP is a major component of transcription, our observations are relevant to the understanding of the gene expression mechanisms underlying normal and pathological cell structure and function.

Nuclear pore complex ion channels (review).

It is currently thought that nuclear pore complexes (NPCs) primarily govern nucleocytoplasmic interactions via selective recognition and active transport of macromolecules. However, in various nuclear preparations, patch-clamp and fluorescence, luminiscence and ion microscopy support classical microelectrode measurements indicating that monoatomic ion flow across the nuclear envelope (NE) is strictly regulated. Gating of large conductance nuclear envelope ion channels (NICs) somewhat resembles that of gap junctional channels. In other respects, NICs are distinct in that they require cytosolic factors, are blocked by wheat germ agglutinin and are blocked and/or modified by antibodies to epitopes of NPC glycoproteins. Therefore, NIC activity, recorded as electrical current/conductance is likely to be intrinsic to NPCs. This observation suggests a potential use for the patch-clamp technique in establishing the mechanisms underlying nuclear pore gating in response to cytosolic and nucleosolic factors such as transcription and growth factors, oncogene and proto-oncogene products and receptors for retinoids, steroids and thyroid hormone. NIC activity may also be useful in evaluating the mechanisms of nuclear import of foreign nucleic acid material such as that contained in virons and viroids. Finally, in consideration to the electrophysiological data accumulated so far, the study of nuclear pore ion channel activity may help our understanding of other important issues such as cell suicide, programmed cell death or apoptosis.

Open states of nuclear envelope ion channels in cardiac myocytes.

Prevalent nucleocytoplasmic transport theory views flow of monoatomic ions as completely unrestricted, resulting from the presence of large diameter pore complexes (NPCs) that perforate, but hold together, the two separate membranes of the nuclear envelope (NE). However, three lines of investigations indicate that, at least in some cell types, monoatomic ion flow is restricted. (i) Patch clamp reveals quantized, ion channel-like activity in several NE preparations; activity thought to result from nuclear ion channels (NICs) connected to NPCs. (ii) Ratiometric fluorescence microscopy demonstrates that ions, as well as small molecules relevant to signal transduction, do distribute as if there is a NE barrier. (iii) Electron microscopy shows that NPCs contain material that behaves like a plug. NICs' large conductance (up to 1,000 pS) makes them a major determinant of nuclear ion concentrations which, in turn, influence nuclear processes. Therefore, NICs are an important modulating force of gene and transcriptional activities--two major determinants of gene expression. As nuclear processes may take from seconds (e.g., signaling) to minutes (e.g., transcription), the time the channels dwell in the ion-conducting open state is relevant to understanding NICs' role in nuclear function. Consequently, dwell-times and lifetimes of open NIC states were studied in 61 patch-clamped adult mouse cardiac myocyte nuclei. Upon voltage stimulation, NICs opened to main states of large conductance (281 +/- 198 pS, range = 120-490 pS, n = 55) and wide-range mean dwell-times (approximately 100 msec, 1-10 sec, and min). Closed states (0 pS) also had widely distributed mean dwell-times (approximately 100 msec, 1-10 sec, and min). Putative open substates (37 +/- 11 pS, range = 25-50, pS, n = 6) of high bursting frequency (< 1 msec) were observed without intervening main states (approximately 5% of patches). Fast (approximately 0.1 msec) and slow (approximately 10 msec) state-transitions were also detected. These observations suggest a role of NICs in mediating cytoplasmic signal control of cardiomyocyte gene expression.

Cell injury and apoptosis.

Various forms of cellular injury, whether induced by immune effector cells, aberrant metabolic processes, chemotherapeutic drugs or temperature shifts, result in common morphological changes consisting of the formation and shedding of membrane vesicles from the injured cell surfaces, i.e., apoptosis. This dynamic cell surface membrane behavior appears to be dependent on the disruption of cytoplasmic microtubules. Concomitant with the altered cell surface morphology, certain physiological and biochemical events have been found to be associated with cell injury. These include changes in membrane permeability, elevated oxygen consumption rates and nuclear DNA fragmentation. However, it remains to be experimentally established which of these biological changes defines a state of irreparable cell injury and/or programmed cell death (PCD). Selective cell injury and death is the goal of many therapeutic modalities aimed at the destruction of malignant cells. On the other hand, prevention of cell injury is desirable in autoimmune diseases such as systemic lupus erythematosus, thyroiditis, insulin dependent diabetes and many others. Injury to the vascular endothelium may play a role not only in thrombosis, atherosclerosis and hypertension, but may also provide the avenues for the metastasis of malignant cells. The objective of the present review is to compare and evaluate the cell injury process induced by effector lymphocytes with that caused by low temperature. The latter mimics most, if not all, the currently known criteria of immune effector cell mediated PCD of target tumor cells.

Restricted ion flow at the nuclear envelope of cardiac myocytes.

Flow of small ions across the nuclear envelope (NE) is thought to occur without restriction through large diameter nuclear pore complexes (NPCs). However, investigations with electron and fluorescence microscopy, and with patch-clamp and microelectrode electrophysiology, suggest that in many animal and plant cell types small ions move through a barrier having the signature of large conductance nuclear ion channels (NICs). As nucleocytoplasmic transport and gene activity are regulated by cytoplasmic signals and as it has recently been shown by this investigator that cardiac NICs are sensitive to cAMP-dependent processes (1), it was considered relevant to further investigate the effects of various cytosolic signals on NIC activity. Ion species substitution demonstrated that K+ is the major species responsible for NIC currents. The Na-channel blocker tetrodotoxin (TTX, 100 microM) and the Ca-channel blocker diltiazem (100 microM) had no effect, indicating no relation of NICs to Na- or Ca-channels in transit to the cell surface membrane. Zn2+ (100 microM) blocked NIC activity, suggesting a dual role in nucleocytoplasmic transport and gene function. GTP did not produce measurable effect. However, its nonhydrolyzable analogue GTP-gamma-S (10 microM) suppressed NIC activity, suggesting a role for GTP hydrolysis in NIC function. Deoxynucleotides (dNTPs, 200 microM) produced a transient increase in NIC activity, pointing to a modulation of NIC function by nucleic acid substrates. These results indicate a role for NICs in mediating: (a) control of gene activity by transduction and other cytosolic signals, and (b) nuclear demands and response to such signals.

Stretch-activated ion channels in tissue-cultured chick heart.

With use of single-channel patch-clamp recording, we found five distinct types of stretch-activated ion channels (SACs) in tissue-cultured embryonic chick cardiac myocytes. With 140 mM K+ saline in the pipette, four channels had linear conductances of approximately equal to 25, 50, 100, and 200 pS and other channel was an inward rectifier of approximately equal to 25 pS at 0 mV membrane potential. The 100- and 200-pS channels were K+ selective, whereas the others passed alkali cations and Ca2+. From reversal potentials, the permeability ratio of K+/Na+, PK/PNa, was 3-7 for nonselective channels and 7-16 for K(+)-selective channels. Channel density was approximately equal to 0.3/microns2 for linear conductances and approximately equal to 0.1/microns2 for inward rectifier. Open-channel noise was a function of pipette filling solution with root-mean-square (RMS) noise increasing in the order K+ < isosmotic sucrose (plus trace ions) < Na+, probably reflecting short-lived block by extracellular ions. All channels were blocked by 20 microM Gd3+. The 25-pS linear channel was also blocked by 12.5 microM tetrodotoxin and 10 microM diltiazem, but the others were insensitive at these concentrations. Extracellular Cs+ and tetraethylammonium chloride did not block any channels. We saw no SAC activity in cells grown without embryo extract (EE), which demonstrates that channel expression, or some necessary cofactor, is under control of growth factors. Basic fibroblast growth factor (FGF) could replace EE in supporting channel expression. The presence of SACs capable of generating inward currents might explain how stretch increases automaticity in the heart. Because some SACs were permeable to Ca2+, they could contribute to the Starling curve and perhaps to initiating stretch-induced hypertrophy.

Nuclear ion channels in cardiac myocytes.

The paradigm that nucleocytoplasmic transport of ions occurs without a diffusional barrier has been challenged by the recent demonstration with patch-clamp techniques of the existence of ion channels in the nuclear envelope of murine zygotes and hepatocytes. This report demonstrates the existence of nuclear ion channels (NIC) in murine ventricular cardiac myocytes. NIC conductance (gamma), calculated from current histogram peaks, was 106-532 pS at 22-36 degrees C. In nucleus-attached patches, replacement of cytoplasmic K+ with Na+ reduced NIC activity within 30 s, suggesting that intranuclear-delimited mechanisms mediate this phenomenon. In excised, inside-out patches K+ was as permeable as Na+ through NIC. NIC activity was observed in 0-4 mM Mg2+ and/or ATP2-, with or without 0-1 mM Ca2+, indicating a minor direct role of these ions. However, in non-responsive excised inside-out patches, NIC activity appeared when the catalytic subunit of the cAMP-dependent protein kinase was applied to the nucleoplasmic side of the patch, in the presence of Mg2+ and ATP2-, indicating an important role for phosphorylation-dependent process(es) in NIC function--an observation supported by the depressing effects of protein kinase inhibitor on responsive NIC. The concept that nucleopore complexes are solely responsible for nucleocytoplamic transport leads to the speculation that these structures are the physical substrate for NIC.

An inexpensive inverted microscope for patch-clamp and other electrophysiological studies at the cellular level.

The popularization of the patch-clamp technique has increased the demand for inverted light microscopes that allow the optimal or almost free movement of patch-clamp pipettes and their support drives. However, commercially available models of inverted microscopes have not been specifically designed for this line of research and, as a consequence, patch-clamp pipette movements are restricted by the small space available between the sample, and the light source and its modulating attachments. This paper provides the details for the construction of a relatively inexpensive inverted microscope that meets the specifications required for patch-clamp and other electrophysiological investigations at the cellular level. The microscope allows the free positioning of the conventional probes for patch-clamp, microelectrode amplifiers, and other micromanipulator probes and attachments. The construction of the microscope is simple and, therefore, since it is relatively inexpensive, the microscope may be easily upgraded in many ways for special purposes, including special optical effects. Finally, although the instrument was developed for patch-clamp and classical electrophysiological studies, it may be used in other types of investigations where freedom of microtool movement is imperative, such as in microsurgery applications.

Stretch-activated channels in heart cells: relevance to cardiac hypertrophy.

Stretch-activated channels have been proposed as the transduction mechanism between load and protein synthesis in cardiac hypertrophy. Under this hypothesis, cardiac deformation is linked to an increased sodium (Na) influx, which, in turn, increases protein synthesis. We have tested whether stretch actually increases Na influx by applying patch-clamp techniques to cultured chick embryo cardiac myocytes and to freshly isolated adult guinea pig cardiomyocytes. Our experiments, in excised and cell-attached patches, revealed the existence of ionic channels that opened, or increased their frequency of opening, upon the application of negative pressures to the lumen of the patch-clamp pipettes. These stretch-sensitive channels allowed the passage of the major monovalent physiological cations, Na and potassium (K), and, to a much lesser extent, the major divalent cations calcium (Ca) and magnesium (Mg). Under normal conditions, the channels had a high open channel noise that prevented the customary, straightforward statistical analysis of single channel data. However, when one of the major monovalent cations was iso-osmotically replaced by sucrose, the open channel noise decreased significantly and permitted a good delineation of the open and closed channel states and, therefore, application of standard patch-clamp, statistical analysis techniques. Under these "sucrose," "monoionic" conditions, the reversal potential was, as one should expect, close to the equilibrium potential for the major monovalent cation present. When high extracellular K solution was used to minimize the cell resting potential, the reversal potential for these stretch-activated currents was estimated to be around -40 mV. Therefore, under normal conditions, stretch should induce an inward, depolarizing current, carried mostly by Na ions.(ABSTRACT TRUNCATED AT 250 WORDS)

Cryopreservation of human heart cells.

Single cells were isolated from human heart specimens and preserved at -56 degrees C in a cryoprotecting solution containing dimethyl sulfoxide. The cells were reanimated by rapid thawing and the properties of the cells were evaluated in a physiological solution. The reanimated cells showed morphological and physiological properties similar to those seen in normal, freshly isolated cells. These results demonstrate the feasibility of storing human heart cells for long-term studies.