GABA neurons in the substantia nigra pars reticulata receive input from GABAergic fibers originating in the forebrain. The role of dopaminergic D1 receptors located on these fibers was investigated using tight-seal whole-cell recordings from visually identified pars reticulata neurons of rat substantia nigra slices. Nondopaminergic pars reticulata neurons were characterized by their electrophysiological properties. Postsynaptic currents evoked by minimal stimulation in the presence of ionotropic glutamate receptor antagonists were blocked by bicuculline, indicating that they were GABAA IPSCs. Evoked GABAA IPSCs were potentiated by D1 receptor agonists. After application of D1 receptor agonists, miniature IPSCs [recorded in the presence of tetrodotoxin (TTX) and the Ca2+ channel blocker Cd2+] increased in frequency but not in amplitude. Effects of D1 receptor stimulation were mimicked by forskolin, as expected, if a cAMP-dependent mechanism was involved. The D1 antagonist SCH23390 blocked the effects of the agonists, and perfusion with SCH23390 resulted in a reduction of evoked IPSCs. In TTX and Cd2+, which prevented dopamine release, the D1 antagonist had no effect on miniature IPSCs. Blocking of monoamine uptake by imipramine increased the amplitude of evoked IPSCs. We conclude that dopamine released from dendrites of dopaminergic neurons enhances GABA release in the pars reticulata of the substantia nigra through D1 receptors presumably located on striatonigral afferents. These D1 receptors, thereby, can reinforce D1 receptor-mediated activation of striatal projection neurons that inhibit the inhibitory output neurons of the basal ganglia in substantia nigra.

Activation of the c-myc oncogene and functional loss of the p53 tumour suppressor gene are among the most frequently recorded genetic lesions in neoplasia but their combined effect has not previously been investigated. By breeding together mice transgenic for human c-myc (CD2-myc) and mice carrying an inactive p53 allele (p53-/-) we found that these genetic lesions act synergistically in vivo. Offspring carrying the CD2-myc transgene and the homozygous p53 null mutation (p53-/-/CD2-myc) were viable but developed thymic lymphomas with dramatically increased frequency and reduced latency compared to both parental groups. The tumour phenotype was similar to that previously recorded for CD2-myc mice (predominantly CD3+, CD4+8+) but tumour clonal complexity and metastasis was significantly greater in the p53-/-/CD2-myc mice. In contrast, no significant increase in tumour incidence was seen in p53+/-/CD2-myc vs p53+/+/CD2-myc mice over a 6 month observation period. However, the loss of wild type p53 in a proportion of tumour cells in p53+/-/CD2-myc lymphomas suggests that wild type allele loss can occur as a late progression step rather than an initiating step in these tumours. We suggest that p53 loss of function may collaborate with the CD2-myc transgene at more than one stage in thymic lymphoma development.

Large vesicles (5-15 microns) were formed by hydrating a dried lipid film containing phospholipids labeled with a fluorophore in one fatty acid chain. By using a fluorescence microscope attached to a low-light-intensity charge-coupled-device camera and digital-image processor, the vesicles were easily viewed and initially showed uniform fluorescence intensity across the surface. The fluorescence pattern of vesicles made with a fluorophore attached to phosphatidylcholine or phosphatidylethanolamine was unaffected by the presence of divalent cations such as Ca2+, Mg2+, Mn2+, Zn2+, or Cd2+. The fluorescence pattern of vesicles containing a fluorophore attached to the acidic phospholipids phosphatidylserine or phosphatidic acid showed distinct differences when treated with Ca2+ or Cd2+, although they were unaffected by Mg2+, Mn2+, or Zn2+. Treatment with 2.0 mM Ca2+ or Cd2+ resulted in the movement of the fluorophore to a single large patch on the surface of the vesicle. When vesicles were formed in the presence of 33 mol % cholesterol, patching was seen at a slightly lower Ca2+ concentration (1.0 mM). The possibility of interactions between Ca2+ and acidic phospholipids in plasma membranes was investigated by labeling erythrocytes and erythrocyte ghosts with fluorescent phosphatidic acid. When Ca2+ was added, multiple (five or six) small patches were seen per individual cell. The same pattern was observed when vesicles formed from whole lipid extracts of erythrocytes were labeled with fluorescent phosphatidic acid and then treated with Ca2+. This shows that the size and distribution of the Ca2+-induced domains depend on phospholipid composition.

1. The functional role of reverse Na(+)-Ca2+ exchange in the activation of contraction of rat ventricular myocytes has been studied. Mechanical activity of single cells, measured as unloaded cell shortening, was recorded simultaneously with membrane current and voltage using a single microelectrode voltage clamp and a video edge detection device. 2. The voltage dependence of contraction was studied by applying trains of depolarizations. At test potentials between +20 and +80 mV (under conditions where large outward currents were activated) a plateau on the shortening vs. voltage (S-V) relationship was observed. Significant cell shortening also occurred at test potentials between -70 and -40 mV; and these contractions were accompanied by large inward Na+ currents. We have investigated the ionic mechanisms for three components of the S-V relation in rat ventricle: (i) shortening which occurs between -70 and -40 mV and is thought to be dependent on the sodium current; (ii) phasic contractions in the voltage range -40 to +40 mV where the L-type Ca2+ current is present; (iii) the plateau of the S-V relation at strongly depolarized voltages where reverse Na(+)-Ca2+ exchange may occur. 3. Experiments in which two independent microelectrode impalements were made in a single myocyte showed that during activation of contraction at test potentials between -70 and -40 mV, and during very large depolarizations (+20 to +80 mV), there were significant deviations of the measured membrane potential from the applied voltages. Activation of cell shortening in these voltage ranges could be eliminated by electronic series resistance compensation, which significantly reduced these voltage errors. Consistent with these findings, when tetrodotoxin (TTX) and 4-aminopyridine (4-AP) were used to block inward Na+ and transient outward K+ currents, respectively, no significant voltage errors were present and a bell-shaped shortening-voltage (S-V) relationship was obtained. 4. When Na+ and K+ currents were blocked, depolarizations from holding potentials of either -80 or -50 mV demonstrated that the threshold for activation of contraction was about -30 mV, and that the voltage dependence of peak shortening was very similar to that of the L-type Ca2+ current (ICa,L). These contractions were suppressed completely by either Cd2+ or ryanodine, showing that activation of cell shortening was due to Ca2+ influx through L-type channels which induced release of Ca2+ from the sarcoplasmic reticulum (SR). No T-type calcium currents were observed.(ABSTRACT TRUNCATED AT 400 WORDS)

The exotoxins produced by certain strains of Staphylococcus aureus are able to stimulate powerful polyclonal proliferative responses and to induce nonresponsiveness by clonal deletion of T lymphocytes expressing the appropriate T-cell antigen receptor V beta gene products. This paper examines the ability of S. aureus enterotoxins to modulate the responsiveness of human CD4+ T lymphocytes with defined antigen specificity. It was observed that certain S. aureus toxins were able to activate and induce anergy in hemagglutinin-reactive T cells expressing V beta 3+ elements. After exposure to S. aureus enterotoxins A, B, and D in the absence of antigen-presenting cells, the T cells failed to respond to their natural ligand presented in an immunogenic form, despite enhanced proliferation to exogenous interleukin 2. The S. aureus toxin-induced anergy was associated with modulation of T-cell membrane receptors; down-regulation of the T-cell antigen receptor was concomitant with enhanced expression of <em>CD2</em> and <em>CD2</em>5. Interestingly, <em>CD2</em>8 was increased only on stimulation, suggesting this protein may be differentially expressed by activated and anergic T cells. These results indicate that bacterial toxins are able to induce antigen-specific nonresponsiveness in human T cells, the application of which may be relevant in the regulation of T cells expressing a particular family of V beta gene products.

Neurons enzymatically isolated from the adult rat superior cervical ganglion (SCG) were investigated using the whole-cell variant of the patch-clamp technique. Current-clamp studies revealed the following mean passive and active membrane properties: resting membrane potential, -54.9 mV; input resistance, 349 M omega; action potential (AP) threshold, -29.8 mV; AP overshoot, 53.3 mV; AP maximum rate of rise, 166.4 V/s; and AP duration, 3.2 ms. Chemosensitivity to acetylcholine remained intact following enzymatic dispersion. Voltage-clamp studies of a transient tetrodotoxin-sensitive Na+ current revealed activation and inactivation processes which could be fit to modified Boltzmann equations. Na+ current activation parameters for the half activation potential (Vh) and slope factor (K) were -23.3 mV and 5.3 mV, respectively. Inactivation parameters for Vh and K were -59.3 mV and 7.6 mV, respectively. Voltage-clamp studies also revealed a high voltage-activated sustained inward current which was eliminated upon removal of external Ca2+, greatly reduced by 500 microM Cd2+, and supported by Ba2+ or Sr2+. Tail current analysis of this Ca2+ current revealed a sigmoidal activation. A low voltage-activated transient Ca2+ current was not observed. We conclude that isolated SCG neurons retain the properties of neurons in intact ganglia and provide several advantages over conventional preparations for the study of voltage-gated membrane currents.

Members of the SLC11 (NRAMP) family transport iron and other transition-metal ions across cellular membranes. These membrane proteins are present in all kingdoms of life with a high degree of sequence conservation. To gain insight into the determinants of ion selectivity, we have determined the crystal structure of Staphylococcus capitis DMT (ScaDMT), a close prokaryotic homolog of the family. ScaDMT shows a familiar architecture that was previously identified in the amino acid permease LeuT. The protein adopts an inward-facing conformation with a substrate-binding site located in the center of the transporter. This site is composed of conserved residues, which coordinate Mn2+, Fe2+ and Cd2+ but not Ca2+. Mutations of interacting residues affect ion binding and transport in both ScaDMT and human DMT1. Our study thus reveals a conserved mechanism for transition-metal ion selectivity within the SLC11 family.

Ion permeation and channel gating are classically considered independent processes, but site-specific mutagenesis studies in K channels suggest that residues in or near the ion-selective pore of the channel can influence activation and inactivation. We describe a mutation in the pore of the skeletal muscle Na channel that alters gating. This mutation, I-W53C (residue 402 in the mu 1 sequence), decreases the sensitivity to block by tetrodotoxin and increases the sensitivity to block by externally applied Cd2+ relative to the wild-type channel, placing this residue within the pore near the external mouth. Based on contemporary models of the structure of the channel, this residue is remote from the regions of the channel known to be involved in gating, yet this mutation abbreviates the time to peak and accelerates the decay of the macroscopic Na current. At the single-channel level we observe a shortening of the latency to first opening and a reduction in the mean open time compared with the wild-type channel. The acceleration of macroscopic current kinetics in the mutant channels can be simulated by changing only the activation and deactivation rate constants while constraining the microscopic inactivation rate constants to the values used to fit the wild-type currents. We conclude that the tryptophan at position 53 in the domain IP-loop may act as a linchpin in the pore that limits the opening transition rate. This effect could reflect an interaction of I-W53 with the activation voltage sensors or a more global gating-induced change in pore structure.

In this study, proliferative responses of human lamina propria T lymphocytes were examined in vitro. The response of lamina propria T lymphocytes to Sepharose-bound anti-CD3 antibody plus interleukin 2 was significantly lower than the response of autologous peripheral blood T lymphocytes, whereas the responses of lamina propria T lymphocytes to anti-T11(2/3) antibodies plus sheep erythrocytes or anti-<em>CD2</em>8 antibody plus interleukin 2 were largely preserved. After coculture with mucosa supernatant, peripheral blood T lymphocytes showed a similar pattern of reactivity as lamina propria T lymphocytes. This reduced reactivity to T-cell antigen receptor stimulation appears to exist at the level of signal transduction, because triggering of CD3 induces low amounts of intracellular inositol 1,4,5-triphosphate and no free calcium increase in lamina propria T lymphocytes when compared with peripheral blood T lymphocytes. This study indicates that the antigen receptor-dependent activation pathway of lamina propria T lymphocytes for proliferation is down-regulated by intestinal mucosa derived factor(s) and that the alternative pathways mediated by <em>CD2</em> or <em>CD2</em>8 are largely preserved. Based on previous data that lamina propria T lymphocytes can provide help to B cells, it is possible that these alternative activation pathways play an important role in T-B cell interaction in the gut.

Catalase (CAT, EC 1.11.1.6) is an important enzyme in antioxidant defense system protecting animals from oxidative stress. Freshwater fish Oreochromis niloticus were exposed for 96 h to different concentrations of Ag(+), Cd(2+), Cr(6+), Cu(2+) and Zn(2+), known to cause oxidative stress, and subsequently CAT activities in liver, kidney, gill, intestine and brain were measured. In vivo, CAT was stimulated by all metals except Ag(+) in the liver and the highest increase in CAT activity (183%) resulted from 1.0 mg Cd(2+)/L exposure, whereas 0.5 mg Ag(+)/L exposure resulted in a sharp decrease (44%). In tilapia kidney, cadmium and zinc had no significant effects on CAT activity, whereas 0.1 mg Cr(6+)/L exposure caused a decrease (44%). Cadmium and zinc did not significantly affect the CAT activity in gill; however, 0.5 mg Ag(+)/L exposure caused an increase (66%) and 1.5 mg Cr(6+)/L exposure caused a decrease (97%) in CAT activity. All metals, except Cu(2+)(41% increase), caused significant decreases in CAT activity in the intestine. In brain, 1.0 mg Zn(2+)/L resulted in an increase in CAT activity (126%), while 1.5 mg Ag(+)/L exposure caused a 54% decrease. In vitro, all metals -- except Ag(+) and Cu(2+) in kidney -- significantly inhibited the CAT activity in all tissues. Results emphasized that CAT may be considered as a sensitive bioindicator of the antioxidant defense system.

Immune-based therapies hold promise for the treatment of multiple myeloma (MM), but so far, immune checkpoint blockade targeting programmed cell death protein 1 has not proven effective as single agent in this disease. T-cell immunoglobulin and ITIM domains (TIGIT) is another immune checkpoint receptor known to negatively regulate T-cell functions. In this study, we investigated the therapeutic potential of TIGIT blockade to unleash immune responses against MM. We observed that, in both mice and humans, MM progression was associated with high levels of TIGIT expression on CD8+ T cells. TIGIT+ CD8+ T cells from MM patients exhibited a dysfunctional phenotype characterized by decreased proliferation and inability to produce cytokines in response to anti-CD3/CD2CD2 or myeloma antigen stimulation. Moreover, when challenged with Vk*MYC mouse MM cells, TIGIT-deficient mice showed decreased serum monoclonal immunoglobulin protein levels associated with reduced tumor burden and prolonged survival, indicating that TIGIT limits antimyeloma immune responses. Importantly, blocking TIGIT using monoclonal antibodies increased the effector function of MM patient CD8+ T cells and suppressed MM development. Altogether our data provide evidence for an immune-inhibitory role of TIGIT in MM and support the development of TIGIT-blocking strategies for the treatment of MM patients.

Cadmium accumulates in the vacuole of plant cells, but the mechanism driving its transport across the vacuole membrane is not understood. Here we present evidence for Cd2+ transport via a Cd2+/H+ antiport activity into tonoplast-enriched vesicles isolated from oat roots. Experimentally, accumulation of Cd2+ into vesicles could be driven by delta pH generated by either V-type ATPase or artificially using nigericin to exchange K+ and H+ in K(+)-loaded vesicles. When tonoplast-enriched vesicles were separated on a linear sucrose gradient, NO3(-)-sensitive ATPase, total MgATPase, and delta pH-dependent Cd2+ transport equilibrated at 1.11 g/ml, the density of tonoplast membrane. Cd2+ accumulation in vesicles was accompanied by efflux of protons in a Cd2+ concentration-dependent manner characteristic of an antiport activity. The delta pH-dependent Cd2+ accumulation process showed saturation kinetics with a Km(app) of 5.5 microM. Thus the process is a candidate for transport of Cd2+ from the cytoplasm to the vacuolar sap under conditions of low as well as high Cd2+ exposure.

1. The ion selectivity and gating of apamin-sensitive, small conductance Ca(2+)-activated K+ (SK) channels were studied in cultured rat adrenal chromaffin cells using patch clamp techniques. 2. The amplitude of slow tail currents showed a bell-shaped dependence on depolarization potentials. Slow tail currents were abolished in a Ca(2+)-free external solution or by adding 100 microM Cd2+ to the external solution. Reversal potentials followed the predictions of the Nernst equation for a K+ electrode. 3. Slow tail currents were largely blocked by external application of apamin (dissociation constant, Kd, 4.4 nM), (+)-tubocurarine (Kd, 20 microM), and tetraethylammonium (Kd, 5.4 mM). 4. The relative permeability (PX/PK, where X may be any one of the ions listed) of SK channels was: Tl+ (1.87)>> K+ (1.0)>> Rb+ (0.81)>> Cs+ (0.16)>> NH4+ (0.11). Na+, Li+ and methylamine were not measurably permeant (PX/PK < 0.005). Open SK channels seem to have an effective pore diameter of 0.34-0.38 nm. The relative conductance (gX/gK) was: Tl+ (1.29)>> K+ (1.0)>> Rb+ (0.85)>> Cs+ (0.45) approximately NH4+ (0.44). 5. With mixtures of Tl+ and K+, SK channels showed anomalous mole-fraction behaviour. 6. Ca2+ dependence of SK channel gating was studied using inside-out macropatches. The [Ca2+] required for half-maximal activation and the Hill coefficient were 0.69 microM and 1.7, respectively, and independent of membrane potentials. 7. Single-channel conductance was 13-14 pS (160 mM K+).

Since 1933, carbonic anhydrase research has focused on enzymes from mammals (alpha class) and plants (beta class); however, two additional classes (gamma and delta) were discovered recently. Cam, from the procaryote Methanosarcina thermophila, is the prototype of the gamma class and the first carbonic anhydrase to be characterized from either an anaerobic organism or the Archaea domain. All of the enzymes characterized from the four classes have been purified aerobically and are reported to contain a catalytic zinc. Herein, we report the anaerobic reconstitution of apo-Cam with Fe2+, which yielded Cam with an effective kcat that exceeded that for the Zn2+-reconstituted enzyme. Mössbauer spectroscopy showed that the Fe2+-reconstituted enzyme contained high spin Fe2+ that, when oxidized to Fe3+, inactivated the enzyme. Reconstitution with Fe3+ was unsuccessful. Reconstitution with Cu2+, Mn2+, Ni2+, or Cd2+ yielded enzymes with effective kcat values that were 10% or less than the value for the Zn2+-reconstituted Cam. Cam produced in Escherichia coli and purified anaerobically contained iron with effective kcat and kcat/Km values exceeding the values for Zn2+-reconstituted Cam. The results identify a previously unrecognized biological function for iron.

The CadC protein from the cadA cadmium resistance operon of Staphylococcus aureus plasmid pI258 regulates transcription of this system in vitro. The CadC protein was overproduced in Escherichia coli cells and partially purified. Gel shift assays of the proposed cadA operator/promoter region DNA showed specific association with the CadC protein. Control arsenic resistance operator/promoter DNA from the same plasmid was not shifted by the CadC protein. Cd2+, Bi3+, and Pb2+ caused the release of CadC from DNA in gel retardation assays. DNase I footprinting measurements showed that the CadC protein specifically associated with and protected a region of operator/promoter DNA from nucleotide positions -7 to +14 relative to the start point of mRNA synthesis. Runoff transcription assays with the operator/promoter region of DNA (plus the first 69 nucleotides of the cadC gene) and purified E. coli RNA polymerase gave an mRNA product of the predicted size. Added CadC protein inhibited transcription in vitro.

BACKGROUND

Podocyte injury and subsequent excretion in urine play a crucial role in the pathogenesis and progression of diabetic nephropathy (DN). Quantification of messenger RNA (mRNA) expression in urinary sediment by real-time PCR is emerging as a noninvasive method of screening DN-associated biomarkers. We hypothesized that the urinary mRNA profile of podocyte-associated molecules may provide important clinical insight into the different stages of diabetic nephropathy.

METHODS

DN patients (N = 51) and healthy controls (N = 13) were enrolled in this study. DN patients were divided into a normoalbuminuria group (UAE<30 mg/g, n = 17), a microalbuminuria group (UAE 30∼300 mg/g, n = 15), and a macroalbuminuria group (UAE>300 mg/g, n = 19), according to their urinary albumin excretion (UAE). Relative mRNA abundance of synaptopodin, podocalyxin, CD2-AP, α-actin4, and podocin were quantified, and correlations between target mRNAs and clinical parameters were examined.

RESULTS

The urinary mRNA levels of all genes studied were significantly higher in the DN group compared with controls (p<0.05), and mRNA levels increased with DN progression. Urinary mRNA levels of all target genes positively correlated with both UAE and BUN. The expression of podocalyxin, CD2-AP, α-actin4, and podocin mRNA correlated with serum creatinine (r = 0.457, p = 0.001; r = 0.329, p = 0.01; r = 0.286, p = 0.021; r = 0.357, p = 0.006, respectively). Furthermore, podocalyxin mRNA was found to negatively correlate with eGFR (r = -0.349, p = 0.01).

CONCLUSIONS

The urinary mRNA profiles of synaptopodin, podocalyxin, CD2-AP, α-actin4, and podocin were found to increase with the progression of DN, which suggested that quantification of podocyte-associated molecules will be useful biomarkers of DN.

The construction and performance characteristics of polymeric membrane electrodes based on two neutral ionophores, N,N'-[bis(pyridin-2-yl)formylidene]butane-1,4-diamine (S1) and N-(2-pyridinylmethylene)-1,2-benzenediamine (S2) for quantification of cadmium ions, are described. The influences of membrane compositions on the potentiometric response of the electrodes have been found to substantially improve the performance characteristics. The best performance was obtained with the electrode having a membrane composition (w/w) of (S1) (2.15%):PVC (32.2%):o-NPOE (64.5%):KTpClPB (1.07%). The proposed electrode exhibits Nernstian response in the concentration range of 7.9x10(-8) to 1.0x10(-1) M Cd2+ with limit of detection 5.0x10(-8) M, performs satisfactorily over wide pH range (2.0-8.0) with a fast response time (10 s). The sensor has been found to work satisfactorily in partially non-aqueous media up to 30% (v/v) content of methanol, ethanol and acetonitrile and could be used for a period of 2 months. The analytical usefulness of the proposed electrode has been evaluated by its application in the determination of cadmium in real samples. The practical utility of the membrane electrode has also been observed in the presence of surfactants.

The cation diffusion facilitators (CDF) are a ubiquitous family of metal transporters that play important roles in homeostasis of a wide range of divalent metal cations. Molecular identities of substrate-binding sites and their metal selectivity in the CDF family are thus far unknown. By using isothermal titration calorimetry and stopped-flow spectrofluorometry, we directly examined metal binding to a highly conserved aspartate in the Escherichia coli CDF transporter YiiP (FieF). A D157A mutation abolished a Cd2+-binding site and impaired the corresponding Cd2+ transport. In contrast, substitution of Asp-157 with a cysteinyl coordination residue resulted in intact Cd2+ binding as well as full transport activity. A similar correlation was found for Zn2+ binding and transport, suggesting that Asp-157 is a metal coordination residue required for binding and transport of Cd2+ and Zn2+. The location of Asp-157 was mapped topologically to the hydrophobic core of transmembrane segment 5 (TM-5) where D157C was found partially accessible to thiol-specific labeling of maleimide polyethylene-oxide biotin. Binding of Zn2+ and Cd2+, but not Fe2+, Hg2+, Co2+, Ni2+, Mn2+, Ca2+, and Mg2+, protected D157C from maleimide polyethylene-oxide biotin labeling in a concentration-dependent manner. Furthermore, isothermal titration calorimetry analysis of YiiP(D157A) showed no detectable change in Fe2+ and Hg2+ calorimetric titrations, indicating that Asp-157 is not a coordination residue for Fe2+ and Hg2+ binding. Our results provided direct evidence for selective binding of Zn2+ and Cd2+ for to the highly conserved Asp-157 and defined its functional role in metal transport.

The role of the interaction of CD2 molecules with lymphocyte function-associated antigen 3 (LFA-3) in facilitating nominal antigen recognition by T lymphocytes was studied by utilizing an HLA-DR4-restricted CD4+ cytotoxic human T-cell clone specific for human immunodeficiency virus envelope glycoprotein gp120 as a responder and murine fibroblasts transfected with human class II major histocompatibility complex (MHC) and/or human LFA-3 molecules as antigen-presenting cells (APC). Although expression of the DR4 restriction element in fibroblasts is sufficient for T-cell recognition of a gp120 peptide as judged by induction of proliferation coexpression of human LFA-3 on DR4+ APC decreases the molar requirement of nominal antigen by greater than one order of magnitude. Both LFA-3 and the relevant class II MHC molecules are necessary for antigen-independent conjugate formation, but the binding is further enhanced by specific nominal antigen. CD2-LFA-3 interaction is independent of T-cell receptor-MHC interaction and contributes directly to the stabilized conjugate between the T cell and LFA-3-bearing APC; soluble CD2 and monoclonal antibodies to LFA-3 and CD2 reduce T-cell-APC binding to the level mediated by nominal antigen and MHC. During conjugate formation, CD2 but not CD3 molecules are reorganized into the cell-cell interaction site in an antigen-independent manner. Thus, reorganization and/or coassociation of CD2 with CD3 molecules is not essential for T-cell activation.

Polyclonal horse antilymphocyte and rabbit antithymocyte globulins (ATGs) are currently used in severe aplastic anemia and for the treatment of organ allograft acute rejection and graft-versus-host disease. ATG treatment induces a major depletion of peripheral blood lymphocytes, which contributes to its overall immunosuppressive effects. Several mechanisms that may account for lymphocyte lysis were investigated in vitro. At high concentrations (.1 to 1 mg/mL) ATGs activate the human classic complement pathway and induce lysis of both resting and phytohemagglutinin (PHA)-activated peripheral blood mononuclear cells. At low, submitogenic, concentration ATGs induce antibody-dependent cell cytotoxicity of PHA-activated cells, but not resting cells. They also trigger surface Fas (Apo-1, CD95) expression in naive T cells and Fas-ligand gene and protein expression in both naive and primed T cells, resulting in Fas/Fas-L interaction-mediated cell death. ATG-induced apoptosis and Fas-L expression were not observed with an ATG preparation lacking CD2 and CD3 antibodies. Susceptibility to ATG-induced apoptosis was restricted to activated cells, dependent on IL-2, and prevented by Cyclosporin A, FK506, and rapamycin. The data suggest that low doses of ATGs could be clinically evaluated in treatments aiming at the selective deletion of in vivo activated T cells in order to avoid massive lymphocyte depletion and subsequent immunodeficiency.

5-Aminolevulinic acid for chlorophyll synthesis in greening barley is formed from glutamate. One of the steps involved in the conversion of glutamate to 5-aminolevulinic acid involves a reduction of glutamyl-tRNA(Glu) to glutamate 1-semialdehyde and tRNA(Glu). An enzyme catalysing this reduction was purified from the stroma of greening barley chloroplasts. An approximately 270-kDa protein composed of 54-kDa identical subunits was identified as the barley glutamyl-tRNA(Glu) reductase after purification by Sephacryl S-300, Cibacron Blue-Sepharose, 2'-5'-ADP-Sepharose, Mono S, Mini Q and Superose 12 chromatography. The sequence of 18 amino acids from the N-terminus of the reductase is 50% identical to a cDNA-deduced domain of the Arabidopsis thaliana hemA protein and encoded in a barley hemA cDNA sequence. This is an unequivocal demonstration that the glutamyl-tRNA(Glu) reductase subunit of higher plants is encoded in a hemA gene of the nuclear genome. Heme at 4 microM concentration or glutamate 1-semialdehyde at 200 microM caused a 50% inhibition of the reductase activity. Micromolar concentrations of Zn2+, Cu2+ and Cd2+ also inhibited barley glutamyl-tRNA(Glu) reductase.

Capsule is an important virulence factor in bacteria. A total of 78 capsular types have been identified in Klebsiella pneumoniae. However, there are limitations in current typing methods. We report here the development of a new genotyping method based on amplification of the variable regions of the wzc gene. Fragments corresponding to the variable region of wzc were amplified and sequenced from 76 documented capsular types of reference or clinical strains. The remaining two capsular types (reference strains K15 and K50) lacked amplifiable wzc genes and were proven to be acapsular. Strains with the same capsular type exhibited ≧94% DNA sequence identity across the variable region (CD1-VR2-CD2) of wzc. Strains with distinct K types exhibited <80% DNA sequence identity across this region, with the exception of three pairs of strains: K22/K37, K9/K45, and K52/K79. Strains K22 and K37 shared identical capsular polysaccharide synthesis (cps) genes except for one gene with a difference at a single base which resulted in frameshift mutation. The wzc sequences of K9 and K45 exhibited high DNA sequence similarity but possessed different genes in their cps clusters. K52 and K79 exhibited 89% wzc DNA sequence identity but were readily distinguished from each other at the DNA level; in contrast, strains with the same capsular type as K52 exhibited 100% wzc sequence identity. A total of 29 strains from patients with bacteremia were typed by the wzc system. wzc DNA sequences confirmed the documented capsular type for twenty-eight of these clinical isolates; the remaining strain likely represents a new capsular type. Thus, the wzc genotyping system is a simple and useful method for capsular typing of K. pneumoniae.

Ca2+ binding is essential for the biological functions of calmodulin (CaM) as a trigger/sensor protein to regulate many biological processes in the Ca2+ -signaling cascade. A challenge in understanding the mechanism of Ca2+ signaling is to obtain site-specific information about the Ca2+ binding properties of individual Ca2+ -binding sites of EF-hand proteins, especially for CaM. In this paper, we report the first estimation of the intrinsic Ca2+ affinities of the four EF-hand loops of calmoduin (I-IV) by individually grafting into the domain 1 of CD2. Taking advantage of the Trp residues in the host protein, we first determined metal-binding affinities for Tb3+, Ca2+, and La3+ for all four grafted EF-loops using Tb3+ aromatic resonance energy transfer. EF-loop I exhibits the strongest binding affinity for Ca2+, La3+, and Tb3+, while EF-loop IV has the weakest metal-binding affinity. EF-loops I-IV of CaM have dissociation constants for Ca2+ of 34, 245, 185, and 814 microM, respectively, with the order I>> III approximately equal to II>> IV. These findings support a charge-ligand-balanced model in which both the number of negatively charged ligand residues and the balanced electrostatic dentate-dentate repulsion by the adjacent charged residues are two major determinants for the relative Ca2+ -binding affinities of EF-loops in CaM. Our grafting method provides a new strategy to obtain site-specific Ca2+ binding properties and a better estimation of the cooperativity and conformational change contributions of coupled EF-hand proteins.

The mechanisms underlying synaptic plasticity can be investigated by analyzing synaptic amplitude fluctuations before and after a synaptic modulation. However, many older fluctuation analysis techniques rely on models of synaptic transmission that incorporate unrealistic simplifying assumptions or have too many free parameters. As a result, these techniques have sometimes produced counterintuitive or contradictory results. In contrast, the variance-mean (V-M) technique requires fewer assumptions and is more robust than previous approaches. It achieves these improvements by focusing on two key parameters of synaptic transmission, the average probability that a vesicle is released from a synaptic terminal following a presynaptic stimulus (Pav), and the average amplitude of the postsynaptic response to a vesicle of transmitter (Qav). To apply V-M analysis, a fluctuating postsynaptic current (PSC) is recorded at several different extracellular Ca2+ or Cd2+ concentrations. The variance of the PSC amplitude is plotted against the mean amplitude at each concentration, forming a parabola. The degree of parabolic curvature estimates Pav, and the limiting slope under low release conditions estimates Qav. The shape of the V-M parabola changes in characteristic ways following each of the three standard forms of synaptic modulation: a change in Qav (postsynaptic), a change in Pav (presynaptic), or a change in the number of terminals (N). The approach does not require specialized software, and can even be implemented as a purely graphical technique. V-M analysis has been used to investigate the site of expression of long-term potentiation and the mechanisms underlying paired-pulse depression. This report presents a detailed mathematical development of the technique, and explores the limiting conditions under which it can confidently be applied. V-M analysis requires fewer than 100 PSC amplitude measurements to accurately estimate Pav and Qav, and it can reliably identify whether a synaptic modulation occurs at a pre- or postsynaptic site. In contrast to other techniques, V-M analysis is largely insensitive to recording noise, nonuniform modulation and intrinsic variability of the unitary synaptic amplitude.