BACKGROUND

Recombinant whole-cell sensors have already proven useful in the assessment of the bioavailability of environmental pollutants like heavy metals and organic compounds. In this work 19 recombinant bacterial strains representing various Gram-positive (Staphylococcus aureus and Bacillus subtilis) and Gram-negative (Escherichia coli, Pseudomonas fluorescens) bacteria were constructed to express the luminescence encoding genes luxCDABE (from Photorhabdus luminescens) as a response to bioavailable heavy metals ("lights-on" metal sensors containing metal-response elements, 13 strains) or in a constitutive manner ("lights-off" constructs, 6 strains).

RESULTS

The bioluminescence of all 13 "lights-on" metal sensor strains was expressed as a function of the sub-toxic metal concentrations enabling the quantitative determination of metals bioavailable for these strains. Five sensor strains, constructed for detecting copper and mercury, proved to be target metal specific, whereas eight other sensor strains were simultaneously induced by Cd2+, Hg2+, Zn2+and Pb2+. The lowest limits of determination of the "lights-on" sensor strains for the metals tested in this study were (microg l-1): 0.002 of CH3HgCl, 0.03 of HgCl2, 1.8 of CdCl2, 33 of Pb(NO3)2, 1626 of ZnSO4, 24 of CuSO4 and 340 of AgNO3. In general, the sensitivity of the "lights-on" sensor strains was mostly dependent on the metal-response element used while the selection of host bacterium played a relatively minor role. In contrast, toxicity of metals to the "lights-off" strains was only dependent on the bacterial host so that Gram-positive strains were remarkably more sensitive than Gram-negative ones.

CONCLUSIONS

The constructed battery of 19 recombinant luminescent bacterial strains exhibits several novel aspects as it contains i) metal sensor strains with similar metal-response elements in different host bacteria; ii) metal sensor strains with metal-response elements in different copies and iii) a "lights-off" construct (control) for every constructed recombinant metal sensor strain. To our knowledge, no Gram-positive metal sensor expressing a full bacterial bioluminescence cassette (luxCDABE) has been constructed previously.

OBJECTIVE

Retinal prosthetic devices are being developed to bypass degenerated retinal photoreceptors by directly activating retinal neurons with electrical stimulation. However, little is known about retinal activity during such stimulation.

METHODS

Whole cell patch-clamp recordings were obtained from ganglion and bipolar cells in the salamander retinal slice preparation. A stimulating electrode was positioned at the vitreal surface of the slice.

RESULTS

Brief pulses of cathodic current evoked transient inward currents in ganglion cells arising from action potentials. Longer pulses (>5 milliseconds) also evoked sustained inward currents in ganglion cells that appeared synaptic in origin because, unlike transient currents, sustained currents were blocked by inhibiting synaptic transmission with Cd2+. These synaptic currents reversed around ECl and were blocked by picrotoxin, strychnine, or both, suggesting they were mediated by GABAa/c and glycine receptors. Synaptic currents were also blocked by the NMDA antagonist MK801 and the KA/AMPA antagonist NBQX, suggesting that epiretinal stimulation evoked glutamate release from bipolar cells, which in turn stimulated the release of GABA and glycine from amacrine cells. Sustained currents were also evoked by epiretinal stimulation in bipolar cells. These currents reversed near ECl and were blocked by picrotoxin, suggesting they arose from GABAa/c receptors.

CONCLUSIONS

Pulse duration is an important parameter for effective activation of the inner retina by epiretinal stimulation. Brief pulses evoke action potentials only in ganglion cells. However, longer pulses also evoke sustained synaptic currents by stimulating glutamate release from bipolar cell terminals, which, in turn, evokes the release of GABA and glycine from amacrine cells.

CS1 is a novel member of the CD2 subset of immunoglobulin superfamily (IgSF) expressed on NK, T and stimulated B cells. The cytoplasmic domain of CS1 contains immunoreceptor tyrosine-based switch motif (ITSM) which is present in 2B4, SLAM and CD84. The signaling adaptor molecule SAP/SH2D1A, the defective gene in X-linked lymphoproliferative disease (XLPD), binds to ITSM and regulates immune cell function. However, recent studies indicate that CS1 may be regulated by a SAP-independent mechanism. In this study, we have examined the ligand specificity of CS1 and the effect of CS1 interaction with its ligand on the cytolytic activity of YT, a human NK cell line. Recombinant fusion protein, CS1-Ig, containing the CS1 extracellular domain and Fc portion of the human IgG bound cells transfected with CS1. CS1-Ig did not show any binding to cells expressing other members of the CD2 family. The cytolytic activity of YT was enhanced in presence of soluble CS1-Ig fusion protein. These results demonstrate that CS1 is a self-ligand and homophilic interaction of CS1 regulates NK cell cytolytic activity.

APOBEC3G is a single-stranded (ss) DNA deaminase that restricts replication of HIV-1 by inducing viral genome mutagenesis through deamination of cytosine to uracil on HIV-1 cDNA. APOBEC3G has polydisperse oligomeric states and deaminates ssDNA processively through jumping and sliding. APOBEC3G has a catalytically inactive N-terminal CD1 domain that mediates processivity and an active C-terminal CD2 domain that catalyzes deaminations. Here, we assess the determinants of APOBEC3G deamination efficiency mediated by the CD1 domain by comparing native APOBEC3G and two CD1 mutants, a monomeric mutant (F126A/W127A) and a clinical mutant associated with high viral loads (H186R). Biochemical assays on ssDNA or partially dsDNA and with a reconstituted HIV replication system demonstrate that both mutants of Apo3G have altered DNA scanning properties in either jumping (F126A/W127A) or sliding (H186R), which results in decreased abilities to induce mutagenesis during reverse transcription. The data reveal a functionality for Apo3G oligomers in deamination and provide the first biochemical characterization of the clinical mutant H186R. The data demonstrate that the balance between the jumping and sliding of Apo3G is needed for efficient mutational inactivation of HIV-1.

Mutations of PCDH15, encoding protocadherin 15, can cause either combined hearing and vision impairment (type 1 Usher syndrome; USH1F) or nonsyndromic deafness (DFNB23). Human PCDH15 is reported to be composed of 35 exons and encodes a variety of isoforms with 3-11 ectodomains (ECs), a transmembrane domain and a carboxy-terminal cytoplasmic domain (CD). Building on these observations, we describe an updated gene structure that has four additional exons of PCDH15 and isoforms that can be subdivided into four classes. Human PCDH15 encodes three alternative, evolutionarily conserved unique cytoplasmic domains (CD1, CD2 or CD3). Families ascertained on the basis of prelingual hearing loss were screened for linkage of this phenotype to markers for PCDH15 on chromosome 10q21.1. In seven of twelve families segregating USH1, we identified homozygous mutant alleles (one missense, one splice site, three nonsense and two deletion mutations) of which six are novel. One family was segregating nonsyndromic deafness DFNB23 due to a homozygous missense mutation. To date, in our cohort of 557 Pakistani families, we have found 11 different PCDH15 mutations that account for deafness in 13 families. Molecular modeling provided mechanistic insight into the phenotypic variation in severity of the PCDH15 missense mutations. We did not find pathogenic mutations in five of the twelve USH1 families linked to markers for USH1F, which suggest either the presence of mutations of yet additional undiscovered exons of PCDH15, mutations in the introns or regulatory elements of PCDH15, or an additional locus for type I USH at chromosome 10q21.1.

These experiments were conducted to determine whether or not sperm motility hyperactivation facilities penetration of the zona pellucida of the oocyte. Two approaches were used. For the first, hamster sperm were incubated for 4.0-4.25 h in a capacitating medium that contained either 2.9 or 25.0 mM sodium bicarbonate. In these media, sperm became equally capacitated as evidenced by their ability to undergo the acrosome reaction when exposed to lysophosphatidyl choline or intact zonae pellucidae; however, sperm became hyperactivated only in the medium containing 25.0 mM bicarbonate. When these sperm were added to cumulus-free oocytes in vitro, only 2 of 88 oocytes were penetrated by sperm preincubated in 2.9 mM bicarbonate, while 31 of 86 oocytes were penetrated by sperm in 25.0 mM bicarbonate. It was found that equal numbers of sperm were bound to the oocytes and that equal numbers were acrosome-reacted on the surface of the zonae in the two media. For the second approach, sperm were incubated in a capacitating medium containing 25 mM bicarbonate. When>> 70% were hyperactivated, aliquots were added to three sets of oocytes. After 10 min had been allowed for sperm to attach and acrosome-react, inhibitors of hyperactivation were added and the sperm and oocytes were incubated for an additional 20 min before fixation and examination for zona penetration. In the dishes treated with the inhibitors verapamil or Cd2+, 1 of 42 and 0 of 42 oocytes were penetrated, respectively, compared with 25 of 40 in controls. Therefore, it appears that hyperactivation facilitates penetration of the hamster zona pellucida.

The immunological effects of recombinant human interleukin 12 (rhIL-12) administration were examined during the conduct of a Phase I clinical trial. Forty patients with advanced cancer received bolus i.v. injections of rhIL-12 in doses ranging between 3 and 1000 ng/kg. Dose-dependent increases in serum IFN-gamma levels were seen during rhIL-12 therapy. Significant lymphopenia was observed 24 h after single i.v. injections of rhIL-12 at each dose level. The degree of lymphopenia was dose dependent, and a plateau effect was seen with rhIL-12 doses of 100 ng/kg and higher. Lymphocyte counts reached nadir levels at approximately 10 h after rhIL-12 injection and returned to baseline within 14 days postinjection. Rebound lymphocytosis, as seen after interleukin 2 therapy, was not observed after recovery from rhIL-12-induced lymphopenia. rhIL-12-induced lymphopenia involved all major lymphocyte subsets, although natural killer (NK) cell numbers were the most profoundly affected, and CD4 T-cell numbers were the least affected. CD2, LFA-1, and CD56 were transiently up-regulated on the surface of NK cells exposed to rhIL-12 in vivo. Peripheral blood mononuclear cells obtained from cancer patients before rhIL-12 therapy exhibited defective NK cell cytotoxicity and T-cell-proliferative responses. Peripheral blood mononuclear cells obtained after lymphocyte recovery following the administration of a single 500 ng/kg dose of rhIL-12 displayed augmented NK cell cytolytic activity in four of four patients tested and enhanced T-cell proliferation in three of four patients tested. These studies confirm that doses of rhIL-12 resulting in significant immunological activity can be administered with acceptable toxicity to cancer patients. Furthermore, rhIL-12 therapy can reverse defects in NK cell and T-cell function that are associated with advanced cancer in humans.

Transposable elements have been used widely in the past 20 years for gene transfer and insertional mutagenesis in Drosophila. Transposon-based technology for gene manipulation and genomic analysis currently is being adopted for vertebrates. We tested the ability of Minos, a DNA transposon from Drosophila hydei, to transpose in mouse tissues. Two transgenic mouse lines were crossed, one expressing Minos transposase in lymphocytes under the control of the CD2 promoter/locus control region and another carrying a nonautonomous Minos transposon. Only mice containing both transgenes show excision of the transposon and transposition into new chromosomal sites in thymus and spleen cells. In addition, expression of Minos transposase in embryonic fibroblast cell lines derived from a transposon-carrying transgenic mouse resulted in excision of the transposon. These results are a first step toward a reversible insertional mutagenesis system in the mouse, opening the way to develop powerful technologies for functional genomic analysis in mammals.

Although the role of glomerular basement membrane has been emphasised as the barrier for retaining plasma proteins in the past three decades, some recent studies have demonstrated that the slit diaphragm of the glomerular epithelial cell (podocyte) is the structure likely to be the barrier in the glomerular capillary wall. Nephrin and podocin were identified as gene products mutated in Finnish-type congenital nephrotic syndrome and autosomal recessive steroid-resistant nephrotic syndrome, respectively. Nephrin s located at the outer leaflet of plasma membranes of the slit diaphragm. Podocin is reported to have an interaction with nephrin. The anti-nephrin antibody is capable of inducing massive proteinuria, which indicates that nephrin is a key functional molecule in the slit diaphragm. The expression of nephrin and podocin was reduced in glomeruli of minimal change nephrotic syndrome, which suggested that the altered expression of these molecules contributes to the development of proteinuria also in acquired diseases. Some recent studies demonstrated that CD2-associated protein (CD2AP) is also a functional molecule in the slit diaphragm, and its expression is altered in membranous nephropathy. These observations suggested that alteration of the molecular arrangement in the slit diaphragm is involved in the development of proteinuria in several kinds of glomerular diseases.

Natural killer (NK) cells play a crucial role in the antitumoral responses through cytolytic function and cytokine production. Expression of HLA-G at the surface of tumoral cells confers a protection against NK-cell cytolysis through its interaction with the ILT2 inhibitory receptor. Even though the role of this interaction on the inhibition of NK-cell cytotoxicity is well established, its effect on the molecular events occurring at the NK/target-cell synapse is not well characterized. We found that the interaction of the inhibitory receptor ILT2 with HLA-G inhibited the polarization of NK-cell lytic granules and the microtubule organizing center (MTOC) as well as the accumulation of filamentous actin (F-actin) at the area of contact. However, it did not affect the recruitment of the activatory receptor CD2 at the NK/target-cell interface. Even though CD2 was accumulated to the NK-cell synapse, the interaction of ILT2 with HLA-G efficiently inhibited intracellular calcium mobilization and IFN-gamma polarized production of NK cells. These results indicate that while the ILT2/HLA-G interaction leads to the inhibition of NK-cell functions, it displays differential effects on cytoskeleton reorganization and CD2 localization at the NK-cell synapse.-Favier, B., LeMaoult, J., Lesport, E., Carosella, E. D. ILT2/HLA-G interaction impairs NK-cell functions through the inhibition of the late but not the early events of the NK-cell-activating synapse.

Rearrangements in the actin cytoskeleton play a pivotal role for costimulation-induced formation of the immunological synapse and T cell activation. Yet, little is known about the actin-binding proteins that link costimulation to rearrangements in the actin cytoskeleton. Here we demonstrate that phosphorylation of the actin bundling protein L-plastin in response to costimulation through TCR/CD3 plus <em>CD2</em> or <em>CD2</em>8, respectively, is important for the activation of human peripheral blood T lymphocytes (PBT). Mass spectrometry and site-directed mutagenesis revealed that Ser5 represents the only phospho-acceptor site of L-plastin in PBT. Wild-type L-plastin (wt-LPL) and a non-phosphorylatable 5A-L-plastin (5A-LPL) equally relocalized to the immunological synapse between PBT and APC. Yet importantly, cells expressing 5A-LPL showed a significantly lower expression of the T cell activation molecules <em>CD2</em>5 and CD69 on the cell surface than cells expressing wt-LPL. This effect is due to a failure in the transport of <em>CD2</em>5 and CD69 to the cell surface since the total amount of these proteins within the cells remained unchanged. In conclusion, phosphorylation of the actin bundling protein L-plastin represents a so-far-unknown mechanism by which costimulation controls the transport of activation receptors to the T cell surface.

These studies examined the expression of the podocyte slit diaphragm protein nephrin and its association with actin at the onset of proteinuria in passive Heymann nephritis (PHN), a rat model of human membranous nephropathy. Four days after immunization, 58% of PHN rats had mild proteinuria. At that time, most slit diaphragms were still visible on electron microscopy; however, in those locations where the deposits encroached on the filtration slits, the slit diaphragms were either displaced or absent. On day 7, the PHN rats were severely proteinuric, and most slit diaphragms were either absent, displaced, or replaced by occluding-type junctions. Immunofluorescence microscopy with antibodies to the external and cytoplasmic domains of nephrin showed a progressive loss of staining and a change in the distribution of nephrin from an interrupted linear pattern in normal controls to a more dispersed and clustered pattern in PHN. In contrast, the intensity of staining for ZO-1 and CD2-associated protein (CD2AP), two other proteins that are located on the cytoplasmic face of the slit diaphragm, was undiminished. Immunogold electron microscopy confirmed the progressive disappearance of nephrin from podocyte foot processes and retention of CD2AP. Glomeruli and glomerular cell membranes were extracted sequentially with Triton X-100, followed by DNase I or potassium iodide to depolymerize actin. Western blot analysis of the extracts showed a progressive decline of total nephrin on days 4 and 7 of PHN as well as a reduction in the actin-associated fraction. These findings show that nephrin partly dissociates from actin at the onset of podocyte injury in PHN. This is accompanied by a progressive loss of nephrin from the podocyte foot processes and prominent changes in the morphology of the slit diaphragms. These events may underlie the loss of podocyte barrier function in membranous nephropathy.

Although most investigators agree that the CD4- CD8- CD3- thymocyte subset represents the most immature intrathymic T cell capable of repopulating the thymus in vivo, little is known of the earliest stages of human T-cell development. Using mAbs to hematopoietic and T-cell lineage molecules in quantitative immunofluorescence studies, new insight has been gained regarding the phenotype of human T-cell precursors before and after colonization of human thymic rudiment. In this article, Barton Haynes and colleagues discuss the sequential expression of CD7, CD4, CD8, CD3, CD2, CD1, CD45, TCR gamma delta and TCR alpha beta, and propose a model defining the stages of T-cell precursors during fetal ontogeny.

Studies were carried out to evaluate the proposed role of indoleamine 2,3-dioxygenase (INDO) induction in the antimicrobial and antiproliferative effects of gamma interferon (IFN-gamma) in human fibroblasts. The INDO cDNA coding region was cloned in the pMEP4 expression vector, containing the metallothionein (MTII) promoter in the sense (+ve) or the antisense (-ve) orientation. Human fibroblasts (GM637) stably transfected with the sense construct expressed INDO activity after treatment with CdCl2 or ZnSO4, but cells transfected with the antisense construct did not. The growth of Chlamydia psittaci was strongly inhibited in INDO +ve cells but not in INDO -ve cells after treatment with Cd2+ or Zn2+. The inhibition correlated with the level of INDO activity induced and could be reversed by the addition of excess tryptophan to the medium. The growth of Toxoplasma gondii was also strongly inhibited in INDO +ve cells but not in INDO -ve cells after treatment with Cd2+. Expression of Cd(2+)-induced INDO activity also inhibited thymidine incorporation and led to cytotoxicity in INDO +ve cells but not in INDO -ve cells. Thus, the induction of INDO activity by IFN-gamma may be an important factor in the antimicrobial and antiproliferative effects of IFN-gamma in human fibroblasts.

In this paper, we examined in detail the ability of anti-1F7 to modulate 1F7 (<em>CD2</em>6) surface expression as well as analyzed the functional relationship between the surface expression of CD3, <em>CD2</em>, and <em>CD2</em>6 and human T cell activation. We showed that anti-1F7-induced modulation is an energy-dependent process that occurs via capping and internalization of the Ag-antibody complex. Although the recovery rate for Ag reexpression of 1F7 following optimal modulation is relatively delayed, reexpression of 1F7 is greatly accelerated following phorbol ester treatment. Most importantly, we demonstrated that modulation of the <em>CD2</em>6 Ag leads to an enhancement in the proliferative activity of modulated human T cells treated with anti-CD3 or anti-<em>CD2</em>, which is preceded by an enhancement in Ca2+ mobilization. <em>CD2</em>6 modulation also led to an increase in anti-CD3- or anti-<em>CD2</em>-mediated T cell clone proliferation. Finally, whereas modulation of the <em>CD2</em>6 Ag has an effect on CD3- or <em>CD2</em>-induced T cell activation, modulation of the CD3/TCR complex inhibits the proliferative response of T cells incubated with anti-CD3 plus anti-1F7 or anti-<em>CD2</em> plus anti-1F7. However, modulation of the <em>CD2</em> structure does not affect anti-CD3- plus anti-1F7-induced human T cell activation. The above results thus provide additional evidence that the <em>CD2</em>6 Ag plays an integral role in the regulation of human T cell activation.

Atrial myocytes have two functionally separate Ca2+ release sites: those in peripheral sarcoplasmic reticulum (SR) adjacent to the Ca2+ channels of surface membrane and those in central SR not associated with Ca2+ channels. Recently, we have reported on the gating of these two different Ca2+ release sites by Ca2+ current. In the present study, we report on the spatiotemporal properties of focal Ca2+ releases (sparks) occurring spontaneously in central and peripheral sites of voltage-clamped rat atrial myocytes, using rapid 2-dimensional (2-D) confocal Ca2+ imaging. Peripheral and central sparks were similar in size and release time (approximately 300 000 Ca2+ ions for congruent with 12 ms), but significantly larger and longer than ventricular sparks. Both sites were resistant to Cd2+ and inhibited by ryanodine. Peripheral sparks were brighter and flattened against surface membrane, had approximately 5-fold higher frequency, approximately 2 times faster diffusion coefficient, and dissipated abruptly. Central sparks, in contrast, occurred less frequently, were elongated along the cellular longitudinal axis, and dissipated slowly. Compound sparks (composed of 2 to 5 unitary focal releases) aligned longitudinally and occurred more frequently at the center. The diversity of peripheral and central sparks with respect to shape, frequency, and speed of spatial development and decay is consistent with regional ultrastructural heterogeneity of SR. The retarded dissipation of central atrial sparks, and high prevalence of compound sparks in cell center may be critical in facilitating the propagation of Ca2+ waves in atrial myocytes lacking t-tubular system and provide the atrial myocytes with functional Ca2+ signaling diversity. The full text of this article is available at http://www.circresaha.org.

Cellular uptake of Cd2+ has been monitored using intracellularly trapped dyes, Fura 2 and Quin 2, which bind Cd2+ with extremely high affinity, and digital fluorescence imaging has been used to visualize intracellular free Cd2+. The excitation spectrum of the Cd2+ complex of Fura 2 is similar to that of the Ca2+ complex, whereas Cd2+ displaces Ca2+ from Quin 2 and reduces fluorescence. Fluorescence of Fura 2-loaded cells increased when 50 microM extracellular Cd2+ was added and fluorescence of Quin 2-loaded cells decreased. Cd2+ uptake by GH3 pituitary cells, which occurs in part via voltage-sensitive L-type calcium channels, was increased by BAY K8644 and depolarization and decreased by nimodipine. When Fura 2 and Quin 2 were used to measure Cd2+ uptake by glial C6 cells, which have no L-channel activity, high K+ and BAY K8644 did not change the apparent rate of Cd2+ uptake. GH3 and C6 cells were incubated with Cd2+ for 24 h and loaded with Fura 2, and fluorescence was measured before and after addition of tetrakis-(2-pyridylmethyl)ethylenediamine (TPEN), a membrane permeant chelator with extremely high affinity for metals. TPEN had little effect on fluorescence of Fura 2-loaded GH3 and C6 cells not exposed to Cd2+ but decreased fluorescence of cells that had been incubated with 1-10 microM Cd2+. Fluorescence ratio imaging of Fura 2-loaded cells was used to image intracellular free Cd2+ for both GH3 and C6 cells. Cd2+ uptake over 30-180 min could be followed by the increase in 340/380 fluorescence ratio and the increase in fluorescence ratio was reversed within 5 min by TPEN. The results provide further evidence for the importance of voltage-gated calcium channels to Cd2+ uptake of certain cells.

The bovine leukemia virus (BLV) is an oncogenic retrovirus that is associated with the development of persistent lymphocytosis (PL) and lymphoma in cattle. While B lymphocytes have been shown to be the primary cellular target of BLV, recent studies suggest that some T lymphocytes and monocytes may be infected by the virus. Because virally altered functions of monocytes and/or T cells could contribute to the development of lymphoproliferative disease, we sought to clarify the distribution of the BLV provirus in subpopulations of peripheral blood mononuclear cells in seropositive cows with and without PL. CD2+ T cells, monocytes, and CD5+ and CD5- B cells were sorted by flow cytometry and tested for the presence of BLV by single-cell PCR. We did not obtain convincing evidence that peripheral blood monocytes or T lymphocytes contain the BLV provirus in seropositive cows with or without PL. In seropositive cows without PL (n=14), BLV-infected CD5+ and CD5- B cells accounted for 9.2% +/- 19% and 0.1% +/- 1.8% of circulating B lymphocytes, respectively. In cows with PL (n=5), BLV-infected CD5+ and CD5- B cells accounted for 66% +/- 4.8% and 13.9% +/- 6.6% of circulating B lymphocytes, respectively. The increase in lymphocyte numbers in cows with PL was entirely attributable to the 45-fold and 99-fold expansions of infected CD5+ and CD5- B-cell populations, respectively. Our results demonstrate that B cells are the only mononuclear cells in peripheral blood that are significantly infected with BLV. On the basis of the absolute numbers of infected cells in seropositive, hematologically normal animals, there appear to be differences in susceptibility to viral spread in vivo that may be under the genetic control of the host.

CzcD from Ralstonia metallidurans and ZitB from Escherichia coli are prototypes of bacterial members of the cation diffusion facilitator (CDF) protein family. Expression of the czcD gene in an E. coli mutant strain devoid of zitB and the gene for the zinc-transporting P-type ATPase zntA rendered this strain more zinc resistant and caused decreased accumulation of zinc. CzcD, purified as an amino-terminal streptavidin-tagged protein, bound Zn2+, Co2+, Cu2+, and Ni2+ but not Mg2+, Mn2+, or Cd2+, as shown by metal affinity chromatography. Histidine residues were involved in the binding of 2 to 3 mol of Zn2+ per mol of CzcD. ZitB transported 65Zn2+ in the presence of NADH into everted membrane vesicles with an apparent Km of 1.4 microM and a Vmax of 0.57 nmol of Zn2+ min(-1) mg of protein(-1). Conserved amino acyl residues that might be involved in binding and transport of zinc were mutated in CzcD and/or ZitB, and the influence on Zn2+ resistance was studied. Charged or polar amino acyl residues that were located within or adjacent to membrane-spanning regions of the proteins were essential for the full function of the proteins. Probably, these amino acyl residues constituted a pathway required for export of the heavy metal cations or for import of counter-flowing protons.

1. Inwardly rectifying currents were characterized in sensory hair cells isolated from the saccules of leopard frogs, using the whole cell configuration of the patch-clamp technique in voltage-clamp mode. 2. Two types of inwardly rectifying currents were distinguishable based on their ionic selectivity, activation and deactivation kinetics, voltage dependence, dependence on external K+ and sensitivity to divalent cations. 3. One inwardly rectifying current displayed K+ selectivity, rapid monoexponential activation (tau approximately 1 ms at -120 mV), steep voltage dependence, dependence of the activation voltage range on external K+ and block by external Ba2+. We refer to this current as IK1, consistent with the terminology used for a similar current in cardiac cells. In 5 mM external K+, IK1 activated negative to -60 mV, was half-activated at -86 mV and fully activated by -110 mV. 4. The other inwardly rectifying current was a mixed K+/Na+ current with slow sigmoidal activation (slow tau approximately 100 ms at -120 mV) and deactivation, shallow voltage dependence and no dependence of the activation curve on external K+ and which was blocked by external Cd2+. This current was called Ih because of its similarities to Ih of photoreceptors. Ih activated negative to -50 mV, was half-activated at -90 mV and was fully activated at -130 mV. 5. A correlation between cell shape and the type of inwardly rectifying current was noted; the more spherical cells had Ih alone and the more cylindrically shaped cells had Ih and IK1. 6. The mean resting potential of 115 cells with IK1 and Ih was -68 +/- 0.5 mV (mean +/- SE) and that of 53 cells with Ih alone was -50 +/- 0.5 mV. This suggests that IK1 contributes to the more negative resting potential of the cylindrical cells. 7. In current-clamp mode, the voltage responses to current steps of the two cell populations differed. Small negative current steps evoked faster, smaller responses in cells with IK1 and Ih than in cells with Ih alone. In cells with Ih alone, long >> 100 ms) negative current steps evoked a hyperpolarization that partly repolarized as Ih activated. Cells with Ih alone showed electrical resonance at rest whereas cells with IK1 resonated only in response to positive current steps. 8. A model developed to explain electrical resonance in bullfrog saccular hair cells was adapted to include Ih or IK1 and Ih.(ABSTRACT TRUNCATED AT 400 WORDS)

We studied natural killer (NK) activity and lymphocyte subsets in 11 active parenteral heroin abusers, 11 long-term methadone-maintained former heroin abusers and 11 apparently healthy individuals. All subjects were males aged 23 to 49 and none had active infectious or inflammatory diseases. All current or former heroin abusers were seronegative for antibody to human immunodeficiency virus. The methadone maintenance patients were socially rehabilitated and had not abused drugs parenterally for at least 10 years. NK activity was determined by a standard Cr-release cytotoxicity assay using K562 cells as targets, and lymphocyte subsets were determined by direct immunofluorescence using flow cytometry. At all three effector-target ratios (100:1, 50:1 and 25:1), NK activity was reduced significantly (P less than .01) in parenteral heroin abusers compared with methadone maintenance patients and apparently healthy individuals. The latter two groups did not differ from each other. Parenteral heroin abusers also had higher absolute numbers of CD2, CD3, CD4 and CD8-positive cells. These data support our hypothesis that significant abnormalities of cellular immunity in parenteral heroin abusers can be normalized by successful long-term methadone treatment.

1. Electrical and pharmacological properties of the low-voltage-activated Ca2+ current (ICa, LVA) in rat aorta smooth muscle cells (SMC) in primary culture were examined, particularly in comparison with the high-voltage-activated Ca2+ current (ICa, HVA). Both types of Ca2+ currents were recorded in external solution containing 20 mM-Ca2+, using the whole-cell voltage-clamp technique. 2. ICa, LVA was evoked by step depolarizations to potentials more positive than -60 mV from a holding potential of -100 mV, and reached a peak in the current-voltage (I-V) relationship around -30 mV. ICa, HVA was activated at -20 mV, and reached a peak at +20 mV. 3. The intracellular dialysis of 5 mM-F- irreversibly suppressed ICa, HVA, with time, while it has little effect on the ICa, LVA. The ICa, LVA could be separated from the ICa, HVA by either selecting the holding and test potential levels or by perfusing intracellularly with F-. 4. The ratio of peak amplitude of Ba2+, Sr2+ and Ca2+ currents in the respective I-V relationship was 1.6:1.2:1.0 for high-voltage-activated Ca2+ channels and was 1.0:1.4:1.0 for low-voltage-activated ones. 5. The inactivation phase of ICa, HVA was fitted by a sum of double-exponential functions, the time constants of which were larger when the current was carried by Ba2+ than by Ca2+. The inactivation time course of ICa, LVA was fitted by a single-exponential function, and the time constant was practically the same when the current was carried by Ba2+ or by Ca2+. Activation and inactivation processes of ICa, LVA were potential-dependent. 6. The steady-state inactivation curve of ICa, LVA was fitted by the Boltzmann equation, having a mid-potential of -80 mV and a slope factor of 5.0. The recovery time course from steady-state inactivation was fitted by a sum of two exponential functions. The time constants of the faster phase were 230 and 380 ms, and those of slower phase were 2.8 and 1.8 s at the repolarization potentials of -120 and -100 mV, respectively. 7. The amplitude of ICa, LVA depended on the external Ca2+ concentration ([Ca2+]o), approaching saturation at 95 mM [Ca2+]o. 8. Various polyvalent cations blocked both types of Ca2+ current reversibly in the order (IC50 in M): La3+ (8 x 10(-8)) greater than Cd2+ (6 x 10(-6)) greater than Ni2+ (1 x 10(-5)) greater than Zn2+ (2 x 10(-5)) for ICa, HVA, and La3+ (6 x 10(-7)) greater than Zn2+ (3 x 10(-5)) greater than Cd2+ (4 x 10(-4)) greater than Ni2+ (6 x 10(-4)) for ICa, LVA.(ABSTRACT TRUNCATED AT 400 WORDS)

OBJECTIVE

The aim was to investigate transient outward currents (I(to)) in single myocytes isolated from human heart muscle specimens which were obtained either from patients in terminal heart failure receiving a transplant or from multiorgan donors whose hearts were not suitable for transplantation.

METHODS

Using the whole cell patch clamp technique, depolarisation dependent I(to) was investigated in these myocytes, and its electrophysiological characteristics compared to I(to) of rat myocytes.

RESULTS

I(to) was observed in ventricular myocytes isolated from failing and non-failing human hearts. The current density of I(to) was similar in cells from failing and non-failing hearts [at +60 mV: 7.9(SEM 1.0) pA.pF-1, n = 9, and 8.7(1.2) pA.pF-1, n = 8, respectively], but smaller in human than in normal rat myocytes, ie, 8.2(0.7) pA.pF-1 (n = 17) v 19.9(2.8) pA.pF-1 (n = 12, six hearts), respectively. Half maximum activation was found at more positive potentials in human than in rat cells, at +21.2(2.0) v +6.4(1.3) mV. In human myocytes, the fraction of non-inactivating outward current at the end of 300 ms long clamp steps was smaller than in rat cells, ie, 22(5%) of peak I(to) in human (n = 17) and 39(5%) in rat cells (n = 12). The potential of half maximum steady state inactivation of rapidly inactivating I(to) in the presence of 0.1 mM Cd2+ was -21.4(0.7) mV in human (n = 15, five hearts), and -35.3(1.0) mV in rat cells (n = 12, six hearts). The late component of outward current showed no potential dependent inactivation in human cells, but underwent steady state inactivation at all potentials positive to -100 mV in rat myocytes. At -100 mV, recovery of I(to) from inactivation took place with a similar time constant, ie, 18(2) ms (n = 7), 24(2) ms (n = 6), and 25(2) ms (n = 4) in cells from three failing and two non-failing human hearts, and from two normal rat hearts, respectively.

CONCLUSIONS

In a limited number of cells, I(to) in human ventricular myocytes shows no dramatic differences between cells derived from failing and non-failing hearts. The characteristics of I(to) in human cells were similar though not identical to I(to) in rat heart cells. This current may be a potential target for antiarrhythmic drug action.

A multifunctional and high-efficiency microfluidic device for droplet generation and fusion is presented. Through unique design of the micro-channels, the device is able to alternately generate droplets, generating droplet ratios ranging from 1 ratio 5 to 5 ratio 1, and fuse droplets, enabling precise chemical reactions in several picoliters on a single chip. The controlled fusion is managed by passive control based on the channel geometry and liquid phase flow. The synthesis of CdS nanoparticles utilizing each fused droplet as a microreactor for rapid and efficient mixing of reagents is demonstrated in this paper. Following alternating droplet generation, the channel geometry allows the exclusive fusion of alternate droplets with concomitant rapid mixing and produces supersaturated solution of Cd2+ and S2- ions to form CdS nanoparticles in each fused droplet. The spectroscopic properties of the CdS nanoparticles produced by this method are compared with CdS prepared by bulk mixing.