Osmotic properties of human lymphocyte

Deep eutectic solvents as cryoprotective agents for mammalian cells

Cryopreservation has facilitated numerous breakthroughs including assisted reproductive technology, stem cell therapies, and species preservation. Successful cryopreservation requires the addition of cryoprotective agents to protect against freezing damage and dehydration. For decades, cryopreservation has largely relied on the same two primary agents: dimethylsulfoxide and glycerol. However, both of these are toxic which limits their use for cells destined for clinical applications. Furthermore, these two agents are ineffective for hundreds of cell types, and organ and tissue preservation has not been achieved. The research presented here shows that deep eutectic solvents can be used as cryoprotectants. Six deep eutectic solvents were explored for their cryoprotective capacity towards mammalian cells. The solvents were tested for their thermal properties, including glass transitions, toxicity, and permeability into mammalian cells. A deep eutectic solvent made from proline and glycerol was an effective cryoprotective agent for all four cell types tested, even with extended incubation prior to freezing. This deep eutectic solvent was more effective and less toxic than its individual components, highlighting the importance of multi-component systems. Cells were characterised post-thawing using atomic force microscopy and confocal microscopy. Molecular dynamics simulations support the biophysical parameters obtained by experimentation. This is one of the first times that this class of solvents has been systematically tested for cryopreservation of mammalian cells and as such this research opens the way for the development of potentially thousands of new cryoprotective agents that can be tailored to specific cell types. The demonstrated capacity of cells to be incubated with the deep eutectic solvent at 37 °C for hours prior to freezing without significant loss of viability is a major step toward the storage of organs and tissues.

The non-contact-based determination of the membrane permeability to water and dimethyl sulfoxide of cells virtually trapped in a self-induced micro-vortex

The cell-membrane permeabilities of a cell type toward water (L_p) and cryoprotective agents (P_s) provide crucial cellular information for achieving optimal cryopreservation in the biobanking industry. In this work, cell membrane permeability was successfully determined via directly visualizing the transient profile of the cell volume change in response to a sudden osmotic gradient instantaneously applied between the intracellular and extracellular environments. A new micro-vortex system was developed to virtually trap the cells of interest in flow-driven hydrodynamic circulation passively formed at the expansion region in a microfluidic channel, where trapped cells remain in suspension and flow with the streamline of the localized vortex, involving no physical contact between cells and the device structure; furthermore, this supports a pragmatic assumption of 100% sphericity and allows for the calculation of the active surface area of the cell membrane for estimating the actual cell volume from two-dimensional images. For an acute T-cell lymphoma cell line (Jurkat), moderately higher values (L_p = 0.34 μm min^-1 atm^-1 for a binary system, and L_p = 0.16 μm min^-1 atm^-1 and P_s = 0.55 × 10^-3 cm min^-1 for a ternary system) were measured than those obtained from prior methods utilizing contact-based cell-trapping techniques, manifesting the influence of physical contact on accuracy during the determination of cell membrane permeability.

Cryopreservation of mammalian cells using protic ionic liquid solutions

Cryopreservation has facilitated considerable advances in both medical technology and scientific research. However, further developments have been limited by the relatively low number of effective cryoprotective agents. Even after fifty years of research, most protocols rely on the same two toxic agents, i.e. dimethylsulfoxide or glycerol. Ionic liquids are a class of promising solvents which are known glass formers and may offer a less-toxic alternative. The research presented here investigates ten protic ionic liquids as potential cryoprotective agents. The liquids are screened for key properties including cellular toxicity, permeability and thermal behaviour. The most promising, ethylammonium acetate, was then tested as a cryoprotective agent on a model cell line and was found to be as effective as the common cryoprotectant, dimethylsulfoxide. This work reports the first use of a protic ionic liquid as an effective cryoprotective agent for a mammalian cell line. This will inform the development of a suite of potential new ionic liquid-based cryoprotectants that could potentially allow the cryopreservation of new cell types.

Effect of plant flavonoids on the volume regulation of rat thymocytes under hypoosmotic stress

BACKGROUND

Cell volume regulation and volume-regulated anion channels are critical for cell survival in non-isosmotic conditions, and dysregulation of this system is detrimental. Although genes and proteins underlying this basic cellular machinery were recently identified, the pharmacology remains poorly explored.

METHODS

We examined effects of 16 flavonoids on the regulatory volume decrease (RVD) of thymocytes under hypoosmotic stress assessed by light transmittance and on the activity of volume-sensitive chloride channel by patch-clamp technique.

RESULTS

Comparison of effects of flavonoids on RVD revealed a group of four active substances with lehmannin being the strongest inhibitor (IC50 = 8.8 μM). Structure-functional comparison suggested that hydrophobicity brought about by methoxy, prenyl or lavandulyl groups as well as by the absence of glucosyl fragment together with localization of the phenyl ring B at the position C2 (which is at C3 in totally inactive isoflavones) are important structural determinants for the flavonoids activity as volume regulation inhibitors. All active flavonoids suppressed RVD under Gramicidin D-NMDG hypotonic stress conditions when cationic permeability was increased by an ionophore, gramicidin D, with all extracellular monovalent cations replaced with bulky NMDG+ suggesting that they target volume-sensitive anionic permeability. While effects of hispidulin and pulicarin were only partial, lehmannin and pinocembrin completely abolished RVD under Gramicidin D-NMDG conditions. In direct patch-clamp experiments, lehmannin and pinocembrin produced a strong inhibiting effect on the swelling-induced whole-cell chloride conductance in a voltage-independent manner.

CONCLUSION

Lehmannin, pinocembrin, and possibly hispidulin and pulicarin may serve as leads for developing effective low-toxic immunomodulators.

Cell membrane permeability coefficients determined by single-step osmotic shift are not applicable for optimization of multi-step addition of cryoprotective agents: As revealed by HepG2 cells

HepG2 cells have a number of research applications and cryopreservation of these cells would improve supply and thus facilitate the study. Development of effective cryopreservation protocols relies on knowledges of the fundamental mass transport characteristics of HepG2 cell membrane. Currently, the permeability parameters estimated from single-step addition are routinely used to predict the osmotic responses of the cells in multistep protocols, as well as used for prediction of optimal cooling rates. However, the reasonability of this approach has not been rigorously studied. Here we measured the hydraulic conductivity (L_p) and the permeability coefficient (P_s) of HepG2 cells in the absence/presence of dimethyl sulfoxide (Me₂SO) at various temperatures with single and multistep addition of Me₂SO. We found that the permeability yielded via one-step addition of the Me₂SO cannot exactly predict the volume change of the cells when the CPA was added in multiple steps.

Determination of the temperature-dependent cell membrane permeabilities using microfluidics with integrated flow and temperature control

We developed an integrated microfluidic platform for instantaneous flow and localized temperature control. The platform consisted of a flow-focusing region for sample delivery and a cross-junction region embedded with a microheater for cell trapping and localized temperature control by using an active feedback control system. We further used it to measure the membrane transport properties of Jurkat cells, including the osmotically inactive cell volume (V_b) and cell membrane permeabilities to water (L_p) and to cryoprotective agent (CPA) solutions (dimethyl sulfoxide (DMSO) in this study) (P_S) at various temperatures (room temperature, 30 °C, and 37 °C). Such characteristics of cells are of great importance in many applications, especially in optimal cryopreservation. With the results, the corresponding activation energy for water and CPA transport was calculated. The comparison of the results from the current study with reference data indicates that the developed platform is a reliable tool for temperature-dependent cell behavior study, which provides valuable tools for general cell manipulation applications with precise temperature control.

Determination of the Membrane Permeability to Water of Human Vaginal Mucosal Immune Cells at Subzero Temperatures Using Differential Scanning Calorimetry

To study mucosal immunity and conduct HIV vaccine trials, it is important to be able to cryopreserve mucosal specimens and recover them in functional viable form. Obtaining a good recovery depends, in part, on cooling the cells at the appropriate rate, which is determined by the rate of water transport across the cell membrane during the cooling process. In this study, the cell membrane permeabilities to water at subzero temperatures of human vaginal mucosal T cells and macrophages were measured using the differential scanning calorimetry method proposed by Devireddy et al. in 1998. Thermal histograms were measured before and after cell lysis using a Slow-Fast-Fast-Slow cooling program. The difference between the thermal histograms of the live intact cells and the dead lysed cells was used to calculate the temperature-dependent cell membrane permeability at subzero temperatures, which was assumed to follow the Arrhenius relationship, [Formula: see text], where Lpg is the permeability to water at the reference temperature (273.15 K). The results showed that Lpg = 0.0209 ± 0.0108 μm/atm/min and Ea = 41.5 ± 11.4 kcal/mol for T cells and Lpg = 0.0198 ± 0.0102 μm/atm/min and Ea = 38.2 ± 10.4 kcal/mol for macrophages, respectively, in the range 0°C to -40°C (mean ± standard deviation). Theoretical simulations predicted that the optimal cooling rate for both T cells and macrophages was about -3°C/min, which was proven by preliminary immune cell cryopreservation experiments.

A study of the osmotic characteristics, water permeability, and cryoprotectant permeability of human vaginal immune cells

Cryopreservation of specimens taken from the genital tract of women is important for studying mucosal immunity during HIV prevention trials. However, it is unclear whether the current, empirically developed cryopreservation procedures for peripheral blood cells are also ideal for genital specimens. The optimal cryopreservation protocol depends on the cryobiological features of the cells. Thus, we obtained tissue specimens from vaginal repair surgeries, isolated and flow cytometry-purified immune cells, and determined fundamental cryobiological characteristics of vaginal CD3⁺ T cells and CD14⁺ macrophages using a microfluidic device. The osmotically inactive volumes of the two cell types (V_b) were determined relative to the initial cell volume (V₀) by exposing the cells to hypotonic and hypertonic saline solutions, evaluating the equilibrium volume, and applying the Boyle van't Hoff relationship. The cell membrane permeability to water (L_p) and to four different cryoprotective agent (CPA) solutions (P_s) at room temperature were also measured. Results indicated V_b values of 0.516 V₀ and 0.457 V₀ for mucosal T cells and macrophages, respectively. L_p values at room temperature were 0.196 and 0.295 μm/min/atm for T cells and macrophages, respectively. Both cell types had high P_s values for the three CPAs, dimethyl sulfoxide (DMSO), propylene glycol (PG) and ethylene glycol (EG) (minimum of 0.418 × 10⁻³ cm/min), but transport of the fourth CPA, glycerol, occurred 50–150 times more slowly. Thus, DMSO, PG, and EG are better options than glycerol in avoiding severe cell volume excursion and osmotic injury during CPA addition and removal for cryopreservation of human vaginal immune cells.

Non-ideal solution thermodynamics of cytoplasm

Quantitative description of the non-ideal solution thermodynamics of the cytoplasm of a living mammalian cell is critically necessary in mathematical modeling of cryobiology and desiccation and other fields where the passive osmotic response of a cell plays a role. In the solution thermodynamics osmotic virial equation, the quadratic correction to the linear ideal, dilute solution theory is described by the second osmotic virial coefficient. Herein we report, for the first time, intracellular solution second osmotic virial coefficients for four cell types [TF-1 hematopoietic stem cells, human umbilical vein endothelial cells (HUVEC), porcine hepatocytes, and porcine chondrocytes] and further report second osmotic virial coefficients indistinguishable from zero (for the concentration range studied) for human hepatocytes and mouse oocytes.

Osmotic stress resistance imparts acquired anti-apoptotic mechanisms in lymphocytes

Apoptosis is a stochastic, physiological form of cell death that is characterized by unique morphological and biochemical properties. A defining feature of apoptosis in all cells is the apoptotic volume decrease or AVD, which has been considered a passive component of the cell death process. Most cells have inherent volume regulatory increase (RVI) mechanisms to contest an imposed loss in cell size, however T-cells are unique in that they do not have a RVI response. We utilized this property to explore potential regulatory roles of a RVI response in apoptosis. Exposure of immature T-cells to hyperosmotic stress resulted in a rapid, synchronous, and caspase-dependent apoptosis. Multiple rounds of osmotic stress followed by recovery of cells in normal media resulted in the development of a population of cells that were resistant to osmotic stress induced apoptosis. These cells were also resistant to other apoptotic stimuli that activate via the intrinsic cell death pathway, while remaining sensitive to extrinsic apoptotic stimuli. Interestingly, these osmotic stress resistant cells showed no increase in anti-apoptotic proteins, and released cytochrome c from their mitochondria following exposure to intrinsic apoptotic stimuli. The osmotic stress resistant cells developed a RVI response, and inhibition of the RVI restored sensitivity to apoptotic agents. Analysis of apoptotic signaling pathways showed a sustained increase in phospho-AKT, whose inhibition also prevented an RVI response resulting in apoptosis. These results define a critical role of volume regulation mechanisms in apoptotic resistance.

A Microfluidic Study of Megakaryocytes Membrane Transport Properties to Water and Dimethyl Sulfoxide at Suprazero and Subzero Temperatures

Megakaryocytes (MKs) are the precursor cells of platelets. Cryopreservation of MKs is critical for facilitating research investigations about the biology of this important cell and may help for scaling-up ex-vivo production of platelets from MKs for clinical transfusion. Determining membrane transport properties of MKs to water and cryoprotectant agents (CPAs) is essential for developing optimal conditions for cryopreserving MKs. To obtain these unknown parameters, membrane transport properties of the human UT-7/TPO megakaryocytic cell line were investigated using a microfluidic perfusion system. UT-7/TPO cells were immobilized in a microfluidic system on poly-D-lysine-coated glass substrate and perfused with various hyper-osmotic salt and CPA solutions at suprazero and subzero temperatures. The kinetics of cell volume changes under various extracellular conditions were monitored by a video camera and the information was processed and analyzed using the Kedem-Katchalsky model to determine the membrane transport properties. The osmotically inactive cell volume (V(b)=0.15), the permeability coefficient to water (Lp) at 37°C, 22°C, 12°C, 0°C, -5°C, -10°C, and -20°C, and dimethyl sulfoxide (DMSO; Ps) at 22, 12, 0, -10, -20, as well as associated activation energies of water and DMSO at different temperature regions were obtained. We found that MKs have relatively higher membrane permeability to water (Lp=2.62 μm/min/atm at 22°C) and DMSO (Ps=1.8×10(-3) cm/min at 22°C) than most other common mammalian cell types, such as lymphocytes (Lp=0.46 μm/min/atm at 25°C). This information could suggest a higher optimal cooling rate for MKs cryopreservation. The discontinuity effect was also found on activation energy at 0°C-12°C in the Arrhenius plots of membrane permeability by evaluating the slope of linear regression at each temperature region. This phenomenon may imply the occurrence of cell membrane lipid phase transition.

Role of potassium and chlorine channels in the regulation of thymocyte volume in rats

Regulatory decrease in thymocyte volume under conditions of osmotic stress was abolished by potassium and chlorine channel blockers. Osmotic stress-activated chlorine channels belong to 2 pharmacological types. The maxi-anion channel is sensitive to Gd(3+). The volume-sensitive outwardly rectifying chlorine channel is inhibited with glybenclamide and phloretin.

Cryopreservation and biophysical properties of articular cartilage chondrocytes

In order to successfully cryopreserve articular cartilage chondrocytes, it is important to characterize their osmotic response during the cryopreservation process, as the ice forms and the solutes concentrate. In this study, experimental work was undertaken to determine the osmotic parameters of articular cartilage chondrocytes. The osmotically inactive volume of articular cartilage chondrocytes was determined to be 44% of the isotonic volume. The membrane hydraulic conductivity parameters for water were determined by fitting a theoretical water transport model to the experimentally obtained volumetric shrinkage data; the membrane hydraulic conductivity parameter L(Pg) was found to be 0.0633 microm/min/atm, and the activation energy E, 8.23 kcal/mol. The simulated cooling process, using the osmotic parameters obtained in this study, suggests a cooling rate of 80 degrees C/min for the cryopreservation of the articular cartilage chondrocytes of hogs. The data obtained in this study could serve as a starting point for those interested in cryopreservation of chondrocytes from articular cartilage in other species in which there is clinical interest and there are no parameters for prediction of responses.

The osmotic characteristics of human fetal liver-derived hematopoietic stem cell candidates

Hematopoietic stem cells derived from fetal liver have promising therapeutic potential for allotransplantation but require a specific protocol to minimize the damage produced by cryopreservation procedures. In this study, a fundamental approach was applied for designing a cell preservation protocol. To this end, the biophysical characteristics that describe the osmotic reaction of CD34(+)CD38(-) human fetal liver stem cell candidates were studied using fluorescent microscopy. The osmotically inactive volume of the stem cell candidates was determined as 48% of the isotonic volume. The permeability coefficients for water and Me(2)SO were determined at T = +22 degree C: L(p) = 0.27 +/- 0.03 microm x min(-1)atm(-1), P(Me(2)SO)) = 2.09 +/- 0.85 x 10 (-4) cm x min(-1), sigma (Me(2)SO)) = 0.63 +/- 0.03 and at T = +12 degree C: L(p) = 0.15 +/-0.02 microm x min(-1)atm(-1), P(Me(2)SO)) = 6.44 +/-1.42 x 10 (-5) cm x min(-1), sigma (Me(2)SO)) = 0.46 +/- 0.05. The results obtained suggest that post-hypertonic and hypotonic stress are the possible reasons for damage to a CD34(+)CD38(-) cell during the cryopreservation procedure.

Aldose reductase induced by hyperosmotic stress mediates cardiomyocyte apoptosis: differential effects of sorbitol and mannitol

Cells adapt to hyperosmotic conditions by several mechanisms, including accumulation of sorbitol via induction of the polyol pathway. Failure to adapt to osmotic stress can result in apoptotic cell death. In the present study, we assessed the role of aldose reductase, the key enzyme of the polyol pathway, in cardiac myocyte apoptosis. Hyperosmotic stress, elicited by exposure of cultured rat cardiac myocytes to the nonpermeant solutes sorbitol and mannitol, caused identical cell shrinkage and adaptive hexose uptake stimulation. In contrast, only sorbitol induced the polyol pathway and triggered stress pathways as well as apoptosis-related signaling events. Sorbitol resulted in activation of the extracellular signal-regulated kinase (ERK), p54 c-Jun N-terminal kinase (JNK), and protein kinase B. Furthermore, sorbitol treatment resulting in induction and activation of aldose reductase, decreased expression of the antiapoptotic protein Bcl-xL, increased DNA fragmentation, and glutathione depletion. Apoptosis was attenuated by aldose reductase inhibition with zopolrestat and also by glutathione replenishment with N-acetylcysteine. In conclusion, our data show that hypertonic shrinkage of cardiac myocytes alone is not sufficient to induce cardiac myocyte apoptosis. Hyperosmolarity-induced cell death is sensitive to the nature of the osmolyte and requires induction of aldose reductase as well as a decrease in intracellular glutathione levels.

Cryopreservation of umbilical cord blood: 1. Osmotically inactive volume, hydraulic conductivity and permeability of CD34(+) cells to dimethyl sulphoxide

Umbilical cord blood (UCB) is an accepted treatment for the reconstitution of bone marrow function following myeloablative treatment predominantly in children and juveniles. Current cryopreservation protocols use methods established for bone marrow and peripheral blood progenitors cells that have largely been developed empirically. Such protocols can result in losses of up to 50% of the nucleated cell population: losses unacceptable for cord blood. The design of optimal cryopreservation regimes requires the development of addition and elution protocols for the chosen cryoprotectant; protocols that minimise damaging osmotic transients. The biophysical parameters necessary to model the addition and elution of dimethyl sulphoxide to and from cord blood CD34(+) cells have been established. An electronic particle counting method was used to establish the volumetric response of CD34(+) cells to changes in osmolality of the suspending medium. The non-osmotic volume of the cell was 0.27 of the cells isotonic volume. The permeation kinetics of CD34(+) cells to water and dimethyl sulphoxide were investigated at two temperatures, +1.5 and +20 degrees C. Values for the hydraulic conductivity were 3.2 x 10(-8) and 2.8 x 10(-7)cm/atm/s, respectively. Values for the permeability of dimethyl sulphoxide at these temperatures were 4.2 x 10(-7) and 7.4 x 10(-6)cm/s, respectively. Clonogenic assays indicated that the ability of CD34(+) cells to grow and differentiate was significantly impaired outside the limits 0.6-4x isotonic. Based on the Boyle van't Hoff plot, the tolerable limits for cell volume excursion were therefore 45-140% of isotonic volume. The addition and elution of cryoprotectant was modelled using a two-parameter model. Current protocols for the addition of cryoprotectant based on exposure at +4 degrees C would require additional time for complete equilibration of the cryoprotectant. During the elution phase current protocols are likely to cause CD34(+) cells to exceed tolerable limits. The addition of a short holding period during elution reduces the likelihood of this occurring.

Osmotic parameters of cells from a bioengineered human corneal equivalent and consequences for cryopreservation

A human corneal equivalent is under development with potential applications in pharmaceutical testing, biomedical research, and transplantation, but the ability to distribute this engineered tissue, depends on successful cryopreservation. Tissue recovery after exposure to conditions during cryopreservation depends on the response of its constituent cells to the changing environment as ice forms and solutes concentrate. This study defines the osmotic properties that define the rate of water movement across the plasma membrane of isolated human corneal endothelial, stroma, and epithelial cells. Cells were transferred from an isotonic (300 mosm/kg) to an anisotonic (150-1500 mosm/kg) solution at constant temperature, and cell volumes monitored using an electronic particle counter. Histograms describing cell volume changes over time after anisosmotic exposure allowed calculation of hydraulic conductivity (L(p)) and osmotically inactive volume fraction (V(b)). Experimental values for L(p) at 4, 13, 22, and 37 degrees C were used to determine the Arrhenius activation energy (E(a)). The L(p) for endothelial, stroma, and epithelial cells at 37 degrees C was 1.98+/-0.32,1.50+/-0.30, and 1.19+/-0.14 microm/min/atm, and the V(b) was 0.28, 0.27, and 0.41, respectively. The E(a) for endothelial, stroma, and epithelial cells was 14.8, 12.0, and 14.1 kcal/mol, respectively, suggesting the absence of aqueous pores. These osmotic parameters and temperature dependencies allow simulation of osmotic responses of human corneal cells to cryopreservation conditions, allowing amount of supercooling to be calculated to indicate the likelihood of intracellular freezing. Simulations show that differences in the osmotic parameters for the constituent cells in the bioengineered cornea result in significant implications for cryopreservation of the engineered corneal equivalent.

Cellular mechanisms for the repression of apoptosis

Apoptosis, also known as programmed cell death, is a ubiquitous mode of cell death known to play an important role during embryogenesis, development, and adult cellular homeostasis. Disruption of this normal physiological cell death process can result in either excessive or insufficient apoptosis, which can lead to various disease states and pathology. Since most cells contain the machinery that brings about apoptosis, it is clear that living cells must contain inherent repressive mechanisms to keep the death process in check. In this review, we examine several modes of repression of apoptosis that exist in cells.

Osmometric and permeability characteristics of human placental/umbilical cord blood CD34+ cells and their application to cryopreservation

The transplantation of placental/cord blood-derived HPC (e.g., CD34+ cells) has become a useful treatment for a broad spectrum of malignant and nonmalignant diseases. The ability to cryopreserve this cell type with high efficiency adds considerable flexibility to cord blood transplantation. The purpose of this study was to develop an understanding of the fundamental cryobiologic factors of these cells, including the osmotic/permeability characteristics, and to use a theoretical approach to optimize freezing procedures. To that end, biophysical parameters, including the osmotically inactive cell volume (Vb), hydraulic conductivity (Lp), and cryoprotectant permeability coefficient (P(CPA)) for DMSO and propylene glycol were measured using a modified Coulter Counter (Coulter Electronics, Inc., Hialeah, FL) at 22 degrees C. In addition, the osmotic tolerance of PCB CD34+ cells was assessed using a colony-forming assay. These experimentally determined parameters were used in a mathematical model to predict optimal cryoprotectant addition and removal procedures. The results demonstrate a Vb of 0.32 x V(iso), an average Lp of 0.17 +/- 0.03 (microm/min/atm +/- SD), and a PCPA of 0.94 +/- 0.004 or 1.0 +/- 0.004 cm/min (x10(-3)) for DMSO or propylene glycol, respectively. No significant difference was determined between the two cryoprotectants used. The osmotic tolerance limits were determined to be 200 and 600 mOsm/kg (1.29 and 0.62 x V(iso), respectively). These results indicate potential benefits of modifications to the widely used method of Rubinstein et al. Proc Natl Acad Sci USA 92:10119-10122, 1995) for cord blood CD34+ cell cryopreservation. As opposed to Rubinstein's method in which DMSO is added to cooled cell suspensions over a 15-min interval, our data indicate that better results may be obtained by introducing and removing the cryoprotectant at ambient temperature over 5 min both to increase viability by avoiding unnecessary risks from osmotic shock and to simplify the protocol. In addition, substitution of propylene glycol for DMSO may be of benefit during the actual freezing and thawing process.

Freezing characteristics of genetically modified lymphocytes for the treatment of MPS II

The freezing characteristics of genetically modified lymphocytes obtained from a donor with mucopolysaccharidosis type II (MPS II) were determined using cryomicroscopy and controlled rate freezing studies to determine postthaw viability. The cells from a donor with MPS II used in this investigation were cultured and transduced with a retroviral vector for the iduronate-2-sulfatase (IDS) enzyme for clinical studies for human gene therapy. The water transport and intracellular ice formation (IIF) characteristics of the cells were determined after completion of the culture and transduction protocol. The water transport parameters, I(pg) and E(lp), for the cultured and transduced cells were determined to be 4.4 +/- 1.3 x 10(-14) m3/Ns and 173 +/- 25 kJ/mol, respectively. The IIF nucleation parameters, kappa and omega, were 5.5 x 10(10) K5 and 3.5 x 10(11) (l/m2 s), respectively. The postthaw viability of the genetically modified cells was less than the viability of the freshly isolated cells from the same donor. The postthaw viability of the cultured and transduced cells from a donor with MPS II was also less than that observed with cells from a normal donor that were frozen and thawed under the same conditions. These studies are essential in understanding the biophysical changes resulting from the ex vivo culture of cells and the manner in which these changes influence the ability of the cells to be cryopreserved.

Physiological significance of volume-regulatory transporters

Research over the past 25 years has identified specific ion transporters and channels that are activated by acute changes in cell volume and that serve to restore steady-state volume. The mechanism by which cells sense changes in cell volume and activate the appropriate transporters remains a mystery, but recent studies are providing important clues. A curious aspect of volume regulation in mammalian cells is that it is often absent or incomplete in anisosmotic media, whereas complete volume regulation is observed with isosmotic shrinkage and swelling. The basis for this may lie in an important role of intracellular Cl- in controlling volume-regulatory transporters. This is physiologically relevant, since the principal threat to cell volume in vivo is not changes in extracellular osmolarity but rather changes in the cellular content of osmotically active molecules. Volume-regulatory transporters are also closely linked to cell growth and metabolism, producing requisite changes in cell volume that may also signal subsequent growth and metabolic events. Thus, despite the relatively constant osmolarity in mammals, volume-regulatory transporters have important roles in mammalian physiology.

A necessary role for cell shrinkage in apoptosis

The loss of cell volume is a fundamental and universal characteristic of programmed cell death. However, what was once thought to be a passive, secondary feature of the cell death process has now become an area of research interest. Recent studies have integrated cell volume regulation and the movement of ions with the activation of apoptosis. A dramatic reduction of potassium and sodium concentration has been shown to occur in apoptotic cells that exhibit a shrunken morphology. Furthermore, maintaining the normal physiological intracellular concentration of monovalent ions, particularly potassium, inhibits the activation and activity of the death cascades. Thus, the role ions play during apoptosis is more extensive than just facilitation of the loss of cell volume. In this article, we will review the concepts of cell volume regulation and the loss of volume during apoptosis. Additionally, we will underscore our current understanding of ion movement as it relates to the activation of the cell death process.

Cloning and functional expression of a new aquaporin (AQP9) abundantly expressed in the peripheral leukocytes permeable to water and urea, but not to glycerol

A new member (AQP9) of the aquaporin family was identified from human leukocytes by homology cloning using PCR. A full length clone was obtained by screening human liver cDNA library. AQP9 encodes a 295-amino-acid protein with the amino acid sequence identity with AQP3 (48%), AQP7 (45%), and other aquaporins (approximately 30%), suggesting that AQP3, AQP7, and AQP9 belong to a subfamily of the aquaporin family. Injection of AQP9-cRNA into Xenopus oocytes stimulated the osmotic water permeability 7-folds with a low activation energy (4.2 kcal/mol) which was inhibited by 0.3 mM mercury chloride by 48%. AQP9 also facilitated urea transport 4-folds. However, in contrast to AQP3 and AQP7, AQP9 did not stimulate the glycerol permeability, suggesting a unique permeability character. Northern blot analysis revealed the high expression of 3.5-kb messages in peripheral leukocytes >> liver > lung = spleen, but not in thymus. The possible role of AQP9 in the immunological function of leukocytes is intriguing and the identification of AQP9 with unique permeability profile may expand our understanding of water and small solute transport in the body.

Fundamental cryobiology of human hematopoietic progenitor cells. I: Osmotic characteristics and volume distribution

While methods for the cryopreservation of hematopoietic stem cells are well established, new sources of progenitor cells, such as umbilical cord blood, fetal tissue, and ex vivo expanded progenitor cells, may require refined protocols to achieve optimal recovery after freezing. To predict optimal protocols for cryopreservation of human hematopoietic progenitors, knowledge of fundamental cryobiological characteristics including cell osmotic characteristics, water and cryoprotectant permeability coefficients of cell membrane, and activation energies of these coefficients is required. In this study, we used CD34+CD33- cells isolated from human bone marrow as hematopoietic progenitor cell models/representatives to study the osmotic characteristics of the progenitor cells. Volume distribution and osmotic behavior of the CD34+CD33- cells were determined using two different methods: (a) a shape-independent electronic sizing technique and (b) a shape-dependent optical image analysis. The cell diameter was measured to be 8.2 +/- 1.1 microns (mean +/- SD, n = 1,091,475, the number of donors = 8) using the electronic sizing technique or 8.7 +/- 1.2 microns (mean +/- SD, n = 1508, the number of donors = 6) by image analysis at initial (isotonic) osmolality, 325 mosm/kg. The cell volume change was measured after the cells were exposed and equilibrated to different anisosmotic conditions. The cell volume was found to be a linear function of the reciprocal of the extracellular osmolality (Boyle van't Hoff plot) ranging from 163 to 1505 mosm/kg. The volume fraction of intracellular water which is osmotically active was determined to be 79.5% of the cell volume. It was concluded that human CD34+CD33- cells osmotically behave as ideal osmometers. This information coupled with cell water and cryoprotectant permeability coefficients as well as their activation energies (to be determined in the ongoing research projects) will be used to design optimum conditions for cryopreservation of human hematopoietic progenitor cells.

Analysis of ion channels by modeling the osmotic effects of weak acids and bases

This paper describes computer programs which may be used to identify and analyze cation and anion channels. Weak acids are used to increase intracellular proton concentrations and by so doing to promote the exchange of osmotically active cations with protons. The time course of cation exchange is readily identified from the changes in cell volume which accompany the net changes in osmotically active cations. Weak bases are used to identify and analyze hydroxyl/anion exchange by a comparable strategy. The model was able to produce data that agreed with experimental data in the literature with an accuracy equal to experimental error. One program, called PROPIONATE, uses the weak acid, propionic acid, to identify cation channels such as the sodium-proton exchanger or the calcium-dependent, potassium channel. A second program, called BASE, is more general because either a weak acid such as propionic acid or a weak base such as ammonia may be used individually or together. When experimental data are available, the programs may be used to calculate permeability coefficients for ion channels and the capacity of intracellular buffers. The programs may be used also in the design of experiments. Initial values may be assigned to intracellular and extracellular electrolyte and proton concentrations. Values for intracellular buffer capacity and channel permeabilities may be chosen. The program will then generate changes in ions, cell volume, and intracellular pH when either a weak acid, a weak base or combination of the two is added to the external medium.

Hydraulic permeability and activation energy of human keratinocytes at subzero temperatures

Studies on isolated human keratinocytes provide a model for design of optimal freeze-thaw protocols for skin cryopreservation and banking. Nucleated keratinocytes from the basal layer of split thickness human cadaveric skin were separated by a combined trypsin and DNAse digestion and suspended in Dulbecco's minimal essential medium with fetal calf serum. A small volume of suspension was frozen on a microprocessor controlled cryostage. Extracellular ice was nucleated at predetermined subzero temperatures, and the temperature was held constant for the duration of the experiment. The osmotic response of the cells to the formation of extracellular ice was recorded on 35-mm photographic film. Selected serial frames were digitized for automated computer evaluation of metric parameters of specific cells. Changes in the apparent cell volume were quantified over a period of several minutes to obtain dehydration curves associated with exposure to concentrated extracellular electrolytes. The Kedem-Katchalsky coupled flow transport model was statistically fit to the data using a personal computer. Values for the permeability coefficients were adjusted to optimize the correlation between the theory and the data. An activation energy of 44.8 kJ/mol and a water permeability of 0.035 micron (atm.min) at 0 degrees C were derived from the data measured over a temperature range from -2 to -9 degrees C.

Volume response of quiescent and interleukin 2-stimulated T-lymphocytes to hypotonicity

Regulatory volume decreased (RVD) in lymphocytes in response to hyptonically induced swelling is dependent on the membrane permeabilities of K+, Cl-, and H2O. We used electronic cell sizing, cell water determination, and the whole cell patch-clamp method to study these membrane permeabilities in the cloned mouse T-lymphocyte, L2. Quiescent L2 cells express low levels of a voltage-gated K+ channel and show no RVD at 25 degrees C. In contrast, L2 cells stimulated to proliferate with the growth factor interleukin 2 have increased K+ conductance and show RVD in response to hypotonicity. RVD in stimulated cells is blocked by quinine and verapamil at levels that also completely block the voltage-gated K+ conductance. Swollen, unstimulated L2 cells can be induced to shrink by addition of the monovalent cation ionophore gramicidin in the presence of impermeant extracellular organic cations; gramicidin also enhances the rate of RVD in stimulated cells. Additionally, the anion transport inhibitor 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS) blocks this gramicidin-facilitated RVD. These results suggest that a minimum requisite Cl- permeability is present even in the unstimulated L2 cells, that a necessary and limiting K+ permeability determines the rate of RVD, and that this K+ permeability increases after growth-factor stimulation as predicted from the direct measurement of voltage-gated K+ conductance. The hydraulic permeability is approximately 70% greater in proliferating L2 cells than in quiescent cells. At 37 degrees C, some RVD occurs in unstimulated L2 cells, and stimulated cells show faster and more complete shrinkage. These results are discussed with respect to the underlying membrane permeabilities and their relation to stimulated cell proliferation.

Kinetics of osmotic water movement in chondrocytes isolated from articular cartilage and applications to cryopreservation

The ability of chondrocytes to survive conditions encountered during cryopreservation depends on the responses of the cells to the physiochemical changes that result when water is removed from the environment of the cells in the form of ice. Cellular responses are therefore closely related to the osmotic permeability properties of the plasma membrane. In order to optimize the conditions for cryopreservation of chondrocytes, osmotic properties of the chondrocyte membrane were determined from the kinetics of volume change in hypertonic solutions at different temperatures. The hydraulic conductivity of the plasma membrane was 0.305 +/- 0.025 micron3/micron2/min/atmosphere at 24 degrees C, with an Arrhenius activation energy of 8.06 kcal/mol. These values are similar to those reported for other cell types, but the osmotically inactive volume of the chondrocytes (0.41 +/- 0.04) was significantly higher than for other cells, implying that chondrocytes have a higher dry weight ratio or that they contain a higher proportion of osmotically inactive or bound water. These results were used to calculate the osmotic responses of chondrocytes at low temperatures and to predict that the least damaging cooling rate for isolated chondrocytes in the absence of cryoprotective compounds is 10 degrees C/min. The ultimate goal of this study is the development of an analytical model applicable to the optimization of techniques for cryopreservation of intact cartilage and other tissues.

Water permeability of human hematopoietic stem cells

It is currently impossible to isolate or identify human hematopoietic progenitor cells from the bone marrow, yet the biophysical properties of these cells are important for the development of techniques to isolate and preserve stem cells for transplantation. Osmotic permeability properties of human bone marrow stem cells were estimated from the kinetics of cell damage in a hypotonic solution measured using in vitro colony assays for multipotential (CFU-GEMM) and committed (BFU-E, CFU-GM) progenitor cells. Cells exposed to a hypotonic solution swell as a result of water influx, and the rate of change of volume is proportional to the hydraulic conductivity of the plasma membrane. Cell damage occurs when the cell volume exceeds the maximum tolerable volume, so the hydraulic conductivity can be estimated from the kinetics of cell damage. For all the progenitor cells studied, the mean value of the hydraulic conductivity was 0.283 micron3/micron2/min/atm at 20 degrees C, with an Arrhenius activation energy of 6.41 kcal/mole. No significant differences were observed in the osmotic properties of the various progenitor cells. These data were used to predict the osmotic responses of human bone marrow stem cells at subzero temperatures during freezing.

Determination of the permeability of human lymphocytes with a microscope diffusion chamber

A diffusion chamber similar to that proposed by J.J. McGrath (J. Microsc., in press) was constructed which allows microscopic observation of osmotically induced volume changes of individual cells in small (microliter) sample volumes. The cells are kept fixed in position in the upper compartment of the chamber by means of a highly permeable membrane and exposed to a step-like change in concentration generated in the lower compartment. An electrical conductivity probe in the upper compartment was used to monitor the temporal change of salt concentration as experienced by the cells. The rise from isotonic to hypertonic can be approximated by an exponential function. Its time constant of tau = 2.08 sec seems to be mainly determined by the change in flushing solution as tau = 1.48 sec was measured with no membrane installed. With human lymphocytes, no loss of cell volume was detected before 5 sec, i.e., when 95% of the final concentration was reached extracellularly. A step change can hence be assumed when modeling exosmosis for determining the lymphocyte membrane permeability. The equations for coupled transport of water and salt were solved numerically and fitted to the experimental data. The results were also compared to various other transport models described in the literature. Human lymphocytes are almost ideally semipermeable with a hydraulic reference permeability of Lp = 4.23 X 10(-4) cm/sec (3.13 X 10(-3) micron X atm-1 X sec-1) at T = 23 degrees C. The temperature and concentration dependence are described by an activation energy Ea = 14.3 kJ/mol and a concentration coefficient alpha 2 = 0.261 osmol/kg. An osmotically inactive volume fraction of 36.9% was determined from the final cell volumes reached asymptotically after shrinkage.

Permeability of cultured megakaryocytopoietic cells of the rat to dimethyl sulfoxide

The permeability of the membrane of the rat megakaryocytopoietic cell to dimethyl sulfoxide was measured to assess its availability to the intracellular compartment. The method used was osmotic, and measured the initial loss of cell water followed by a reswelling to isotonic volume when cells were placed in culture media containing 0.6 M DMSO. Values for the hydraulic coefficient, Lp, the permeability of the membrane to DMSO, wRT , and the reflection coefficient were calculated from the equations of Kedem and Katchalsky . The average value at 25 degrees C for Lp was 0.46 micron min-1 atm1 ; wRT was 9.3 micron min-1, and the reflection coefficient was 0.65. At these cell volumes, 50% equilibration occurred in 5 sec. Cells equilibrated in 0.6 M DMSO increased their volume of osmotically inactive water. Coupled with this phenomenon of stabilization of water was a reduction in the hydraulic coefficient by 50%. These findings are discussed in the context of current hypotheses about cellular viability during freezing and thawing in the presence and absence of cryoprotectants.

Responses of lymphocytes to anisotonic media: volume-regulating behavior

The regulatory responses elicited in lymphoid cells suspended in anisotonic media are reviewed. The immediate response approximates osmometric behavior. In addition, in hypotonic media, the initial osmometric swelling is followed by a regulatory volume decrease (RVD), which is associated with KCl loss. The volume-induced effluxes of K+ and Cl- are mediated by two independent conductive pathways. Ca2+-depletion experiments and studies of inhibitor susceptibility suggest that Ca2+ may mediate the activation of the K+ pathway. The responses of the two main lymphocyte subpopulations to hypotonic challenge are different. RVD is much more rapid in T- than in B-cells, regardless of their tissue of origin. Under certain conditions, shrunken lymphocytes will regain their initial volume. This regulatory volume increase (RVI) is due to NaCl uptake, followed by a secondary exchange of Na+ for K+ via the Na+-K+ pump. Na+ is primarily taken up in exchange for H+ through an amiloride-sensitive pathway, whereas Cl- enters in exchange for HCO-3 (or OH-). Anion and cation fluxes responsible for RVI are electroneutral. Some of the volume-sensitive pathways can also be activated in isotonic cells. The conductive K+ pathway is activated by Ca2+ plus ionophore A23187, and the Na+-H+ exchanger can be activated by cytoplasmic acidification. The responses of lymphocytes to anisotonic challenge are compared with those of other cells, and the possible significance of the volume-induced fluxes is discussed.

Inactivation of regulatory volume decrease in human peripheral blood lymphocytes by N-ethylmaleimide

The sulfhydryl group reagent N-ethylmaleimide was found to inhibit in a dose dependent manner regulatory volume decrease of human peripheral lymphocytes swollen in buffered hyposmotic NaCl media. In hyposmotic KCl media NEM treated lymphocytes prevented an additional secondary swelling seen in control lymphocytes. The data suggest that N-ethylmaleimide acts on ion transport mechanisms involved in volume regulatory changes. This effect contrasts with the stimulation by N-ethylmaleimide of apparently volume sensitive K/Cl fluxes in certain mammalian red cells.

Volume regulation of human peripheral blood lymphocytes and stimulated proliferation of volume-adapted cells

Human peripheral blood lymphocytes exposed to hypotonic media (Ca/Mg-free, room temp.) first swell and then shrink. This shrinking response is characterized by a simple exponential with a half-time of 1.44 +/- 0.60 min (n = 11) and its extent but not the half-time for a given hypotonicity is influenced by [K+]0. Using K-selective electrodes, we observe a change in [K+]0 when cells are diluted into hypotonic media. A half-time of 1.55 +/- 0.06 min (n = 4) was obtained. A similar half-time was obtained by assay of total cell K using atomic absorption spectroscopy. At all osmolarities [K+]i was decreased from control values and was constant as [K+]0 was increased. Short-term incubation with ouabain (10(-4) M) had no effect. Decreasing osmolarities progressively inhibited phytohemagglutinin-stimulated DNA synthesis, yet cell number and viability remained unaltered. Our evidence indicates that the volume response is mediated by a change in the passive permeability of the plasma membrane to K and/or to the accompanying anions, and that the consequently volume-adapted cells are growth-inhibited.

Volume regulation by human lymphocytes. Role of calcium

Human peripheral blood lymphocytes regulate their volumes in hypotonic solutions. In hypotonic media in which Na+ is the predominant cation, an initial swelling phase is followed by a regulatory volume decrease (RVD) associated with a net loss of cellular K+. In media in which K+ is the predominant cation, the rapid initial swelling is followed by a slower second swelling phase. 86Rb+ fluxes increased during RVD and returned to normal when the original volume was approximately regained. Effects similar to those induced by hypotonic stress could also be produced by raising the intracellular Ca++ level. In isotonic, Ca++-containing media cells were found to shrink upon addition of the Ca++ ionophore A23187 in K+-free media, but to swell in K+-rich media. Exposure to Ca++ plus A23187 also increased 86Rb+ fluxes. Quinine (75 microM), an inhibitor of the Ca++-activated K+ pathway in other systems blocked RVD, the associated K+ loss, and the increase in 86Rb+ efflux. Quinine also inhibited the volume changes and the increased 86Rb fluxes induced by Ca++ plus ionophore. The calmodulin inhibitors trifluoperazine, pimozide and chlorpromazine blocked RVD as well as Ca++ plus A23187-induced volume changes. Trifluoperazine also prevented the increase in 86Rb+ fluxes and K+ loss induced by hypotonicity. Chlorpromazine sulfoxide, a relatively ineffective calmodulin antagonist, was considerably less potent as an inhibitor of RVD than chlorpromazine. It is suggested than an elevation in cytoplasmic [Ca++], triggered by cell swelling, increases the plasma membrane permeability to K+, the ensuing increased efflux of K+, associated anions, and osmotically obliged water, leading to cell shrinking (RVD).

Cation fluxes and volume regulation by human lymphocytes

The ionic basis of volume regulation by human peripheral blood lymphocytes in hypotonic Tyrode's medium has been studied. The intracellular water space of lymphocytes increased to a maximum after 1 min in 0.68 X isotonic Tyrode's but returned to the isotonic value by 20 min at 37 degrees C. During this phase of volume regulation (1-20 min) both 42K+ efflux and 42K+ influx were stimulated severalfold, but the increase in 42K+ efflux exceeded the influx, resulting in a net loss of 20% of the lymphocyte K+. The increase in 42K+ efflux during the phase of cell shrinkage was unaffected by ouabain or by quinidine. Hypotonicity increased both the ouabain-sensitive (active) and ouabain-insensitive components of 42K+ influx by 76% and 123% respectively. Hypotonic shock stimulated 22Na+ influx by only 25%, but cell Na+ content was unchanged at 1 min and even decreased after 20 min. Thus active K+ influx and Na+ extrusion is increased by hypotonicity, but greater pumping cannot explain the net decrease in cell cations that leads to volume regulation. The 45Ca2+ uptake was not significantly changed by hypotonicity. Although volume regulation was abolished in a hypotonic high K medium, 42K+ efflux was still stimulated 2-fold by the reduction in tonicity. These findings support the hypothesis that volume regulation in hypotonic media occurs largely by a passive loss of cell K+, which results from a selective increase in membrane permeability to this ion. The increase in K+ permeability in hypotonic media is observed even in the absence of volume regulation by the cell.

Osmotic permeability of Novikoff hepatoma cells

The osmotic permeability coefficient (Pf) for water movement across Novikoff hepatoma cells was found to be 82 +/- 3 (S.E.) x 10(-5) cm . s-1 at 20 degrees C. The corresponding diffusional permeability coefficient for 3HHO (Pd) was 97 +/- 10 (S.E.) . 10(-5) cm . s-1, therefore the ratio Pf/Pd is close to unity. The apparent activation energy for water filtration was 10.4 +/- 0.4 (S.E.) kcal . mol-1. This value is significantly greater than the activation energy for the self diffusion of water. The product of the hydraulic permeability coefficient and the viscosity coefficient for water was temperature-dependent. However, the product of the hydraulic permeability coefficient and the viscosity coefficient for membrane lipid did not vary with temperature. These data are interpreted as evidence for water movement across a lipid membrane barrier rather than through aqueous channels.

Permeability of Novikoff hepatoma cells to water and monohydric alcohols

The permeability coefficients of Novikoff hepatoma ascites cell membranes for tritiated water (3HHO) and for a homologous series of monohydric alcohols (methanol through hexanol) were deduced from linear diffusion coefficients by means of a series-parallel pathway model (Redwood et al. (1974) J. Gen. Physiol. 64, 706-729). Membrane permeability coefficients for 3HHO at 20, 30 and 37 degrees C were (all x 10(-5)) 97, 125, and 163 cm . s-1, respectively, and were significantly smaller than the corresponding values for the alcohols tested. In the alcohols series, ethanol had the lowest permeability coefficient 198 x 10(-5) cm . s-1 at 20 degrees C. The apparent activation energy for water permeation was 6.7 +/- 1.9 S.E. kcal . mol-1. The apparent membrane diffusion coefficients for the alcohols were a complex function of molecular properties with less diffusional membrane resistance to the alcohols in the middle of the homologous series than would have been expected on the basis of oil-water partitioning or molar volume considerations. The conventional parallel aqueous lipophilic pathway model is not consistent with the present data which can be interpreted by consideration of parallel lipophilic pathways through the Novikoff hepatoma cell membrane.

Lymphocyte response to phytohemagglutinin: intracellular volume and intracellular [K+]

The effect of phytohemagglutinin (PHA) on lymphocytes was examined with respect to free intracellular water volume and intracellular [K+]. At a cell concentration of 30 X 10(6) lymphocytes/ml in modified Hank's Buffered Salt Solution (HBSS) in the presence of 10% human AB serum, addition of PHA at 3 mg/ml resulted in a 24-27% decrease in free intracellular water space within 30 to 60 minutes and a return to control level after three hours. A larger change in intracellular water (44%) was observed under similar conditions in the absence of serum. The absolute intracellular K+ content did not change after PHA addition, but the cell water volume decrease arising from PHA addition resulted in a 29% increase in intracellular [K+] at 60 minutes. The decrease in lymphocyte water volume induced by PHA was also observed for concanavalin A which stimulates lymphocyte proliferation, but not for wheat germ lectin, an agglutinating agent which is not mitogenic. Thus, volume regulation may be closely associated with the mitogenicity of these compounds.