HSV-2 Specifically Down Regulates HLA-C Expression to Render HSV-2-Infected DCs Susceptible to NK Cell Killing

Both NK cells and CTLs kill virus-infected and tumor cells. However, the ways by which these killer cells recognize the infected or the tumorigenic cells are different, in fact almost opposite. CTLs are activated through the interaction of the TCR with MHC class I proteins. In contrast, NK cells are inhibited by MHC class I molecules. The inhibitory NK receptors recognize mainly MHC class I proteins and in this regard practically all of the HLA-C proteins are recognized by inhibitory NK cell receptors, while only certain HLA-A and HLA-B proteins interact with these receptors. Sophisticated viruses developed mechanisms to avoid the attack of both NK cells and CTLs through, for example, down regulation of HLA-A and HLA-B molecules to avoid CTL recognition, leaving HLA-C proteins on the cell surface to inhibit NK cell response. Here we provide the first example of a virus that through specific down regulation of HLA-C, harness the NK cells for its own benefit. We initially demonstrated that none of the tested HSV-2 derived microRNAs affect NK cell activity. Then we show that surprisingly upon HSV-2 infection, HLA-C proteins are specifically down regulated, rendering the infected cells susceptible to NK cell attack. We identified a motif in the tail of HLA-C that is responsible for the HSV-2-meduiated HLA-C down regulation and we show that the HLA-C down regulation is mediated by the viral protein ICP47. Finally we show that HLA-C proteins are down regulated from the surface of HSV-2 infected dendritic cells (DCs) and that this leads to the killing of DC by NK cells. Thus, we propose that HSV-2 had developed this unique and surprising NK cell-mediated killing strategy of infected DC to prevent the activation of the adaptive immunity.     

Site-specific cleavage of RNA and DNA by complementary DNA--bleomycin A5 conjugates

Bleomycin displays clinical chemotherapeutic activity, but is so nonspecifically toxic that it is rarely administered. It was therefore of interest to determine whether bleomycin could be directed to cleave RNA or DNA at a specific site by conjugation to a complementary oligonucleotide. A 15 nt MYC complementary oligodeoxynucleotide (HMYC55) bearing a 5' bleomycin A5 (Blm) residue was designed to base-pair with nt 7047-7061 of human MYC mRNA. Reactivity of the Blm-HMYC55 conjugate (and mismatch controls) with a MYC mRNA 30-mer, a MYC DNA 30-mer, and a MYC 2'-O-methyl RNA 30-mer, nt 7041-7070, was analyzed in 100 microM FeNH(4)SO(4), 50 mM beta-mercaptoethanol, 200 mM LiCl, 10 mM Tris-HCl, pH 7.5, at 37 degrees C. Cleavage of the substrate RNA or DNA occurred primarily at the junction of the complementary DNA-target RNA duplex, 18-22 nt from the 5' end of the RNA. Reaction products with lower mobility than the target RNA or DNA also formed. Little or no reaction was observed with more than three mismatches in a Blm-oligodeoxynucleotide conjugate. Neither the short RNA or DNA cleavage fragments nor the low mobility products were observed in the absence of Fe(II), or the presence of excess EDTA. The target RNA was also cleaved efficiently by bleomycin within a hybrid duplex with a preformed single-nucleotide bulge in the RNA strand. New Blm-oligodeoxynucleotide conjugates containing long hexaethylene glycol phosphate based linkers between oligodeoxynucleotide and bleomycin were designed to target this bulge region. These conjugates achieved 8-18% cleavage of the target RNA, depending on the length of the linker. Blm-oligodeoxynucleotide conjugates thus demonstrated sequence specificity and site specificity against RNA and DNA targets.     

Effects of temperature on phyllody expression and cytokinin content in floral organs of rose flowers

Formation of leaf-like organs known as phylloids in Rosahybrida cv. Motrea flowers was promoted by exposure of plants toelevated temperatures. At a day/night temperature regime of26°C/21°C respectively theproportion of malformed flowers exhibiting phyllody was four times higher thanthat in flowers of plants grown at21°C/15°C. The number ofpetals in phyllody-expressing flowers was higher than that in normal flowers.The total content of endogenous cytokinins in young flower buds of plantsexposed to the lower temperature was six times higher than that at the highertemperatures. The effects of the reduced temperature were pronounced on all thegroups of cytokinins examined. However, the proportion of the various cytokiningroups remained similar at both temperature regimes. In contrast to thecytokinins in the flower buds, the content of all cytokinin types in youngleaves increased following exposure to the higher temperature and was reducedbythe lower temperatures. After 11 weeks at the lower temperature, about18% of the flowers remained malformed, whereas at the higher temperatureabout 20% of the flowers still remained normal. All thephyllody-exhibiting flowers were formed on vigorously grown basal shootscharacteristic to Rosa hybrida plants, whereas the normalflowers at the elevated temperatures were formed on lateral shoots which weremost distal to the plant base. However, irrespective of the season, thepresenceof normal and malformed flowers was observed on plants kept growing at standardconditions of 30°C/17°C inthegreenhouse. This phenomenon led us to examine the cytokinins in floral organsofnormal and malformed cv. Motrea flowers grown in the greenhouse as well as inflowers of a complete rose mutant known as a 'Green Rose(Rosa chinensis viridiflora). The highest content ofcytokinins was found in the pistils and stamens of normal 'Motreaflowers. On the other hand, the content of cytokinins in leaf-like style-tubesin the malformed flowers as well as in partially malformed ovaries at the baseof phylloids was significantly lower. A low content of cytokinins was alsopresent in petals of both normal and phyllody-exhibiting flowers and the lowestcontent has been found in the phylloids of the 'Green Rose. Apossibility of mutant deviations in metabolism of cytokinins in rose plants isdiscussed.     

Knockdown of CENH3 in Arabidopsis reduces mitotic divisions and causes sterility by disturbed meiotic chromosome segregation

The histone H3 variant (CENH3) of centromeric nucleosomes is essential for kinetochore assembly and thus for chromosome segregation in eukaryotes. The mechanism(s) that determine centromere identity, assembly and maintenance of kinetochores are still poorly understood. Although the role of CENH3 during mitosis has been studied in several organisms, little is known about its meiotic function. We show that RNAi-mediated CENH3 knockdown in Arabidopsis thaliana caused dwarfism as the result of a reduced number of mitotic divisions. The remaining mitotic divisions appeared to be error-free. CENH3 RNAi transformants had reduced fertility because of frequently disturbed meiotic chromosome segregation. N-terminally truncated EYFP-CENH3(C) is deposited to and functional within Arabidopsis centromeres of mitotic chromosomes, but cannot be loaded onto centromeres of meiotic nuclei. Thus the N-terminal part is apparently required for CENH3 loading during meiosis. EYFP-CENH3(C) expression reduces the amount of endogenous CENH3, thus mimicking the effect of RNAi. The consequences of reduced endogenous CENH3 and lack of meiotic incorporation of EYFP-CENH3(C) are reduced fertility caused by insufficient CENH3 loading to the centromeres of meiotic chromosomes, subsequent lagging of chromosomes and formation of micronuclei.     

Three routes to suppression of the neurodegenerative phenotypes caused by Kinesin heavy chain mutations

Kinesin-1 is a motor protein that moves stepwise along microtubules by employing dimerized kinesin heavy chain (Khc) subunits that alternate cycles of microtubule binding, conformational change, and ATP hydrolysis. Mutations in the Drosophila Khc gene are known to cause distal paralysis and lethality preceded by the occurrence of dystrophic axon terminals, reduced axonal transport, organelle-filled axonal swellings, and impaired action potential propagation. Mutations in the equivalent human gene, Kif5A, result in similar problems that cause hereditary spastic paraplegia (HSP) and Charcot-Marie-Tooth type 2 (CMT2) distal neuropathies. By comparing the phenotypes and the complementation behaviors of a large set of Khc missense alleles, including one that is identical to a human Kif5A HSP allele, we identified three routes to suppression of Khc phenotypes: nutrient restriction, genetic background manipulation, and a remarkable intramolecular complementation between mutations known or likely to cause reciprocal changes in the rate of microtubule-stimulated ADP release by kinesin-1. Our results reveal the value of large-scale complementation analysis for gaining insight into protein structure-function relationships in vivo and point to possible paths for suppressing symptoms of HSP and related distal neuropathies.     

A New C-Terminal Cleavage Product of Procaspase-8, p30, Defines an Alternative Pathway of Procaspase-8 Activation

Caspase-8 is the main initiator caspase in death receptor-induced apoptosis. Procaspase-8 is activated at the death-inducing signaling complex (DISC). Previous studies suggested a two-step model of procaspase-8 activation. The first cleavage step occurs between the protease domains p18 and p10. The second cleavage step takes place between the prodomain and the large protease subunit (p18). Subsequently, the active caspase-8 heterotetramer p18₂-p10₂ is released into the cytosol, starting the apoptotic signaling cascade. In this report, we have further analyzed procaspase-8 processing upon death receptor stimulation directly at the DISC and in the cytosol. We have found an alternative sequence of cleavage events for procaspase-8. We have demonstrated that the first cleavage can also occur between the prodomain and the large protease subunit (p18). The resulting cleavage product, p30, contains both the large protease subunit (p18) and the small protease subunit (p10). p30 is further processed to p10 and p18 by active caspases. Furthermore, we show that p30 can sensitize cells toward death receptor-induced apoptosis. Taken together, our data suggest an alternative mechanism of procaspase-8 activation at the DISC.Apoptosis can be triggered by a number of factors, including UV or γ-irradiation, chemotherapeutic drugs, and signaling from death receptors (11, 12). CD95 (APO-1/Fas) is a member of the death receptor family, a subfamily of the tumor necrosis factor receptor (TNF-R) superfamily (1, 30). Eight members of the death receptor subfamily have been characterized so far: TNF-R1 (DR1, CD120a, p55, p60), CD95 (DR2, APO-1, Fas), DR3 (APO-3, LARD, TRAMP, WSL1), TRAIL-R1 (APO-2, DR4), TRAIL-R2 (DR5, KILLER, TRICK2), DR6, EDA-R, and NGF-R (13). Cross-linking of CD95 by its natural ligand, CD95L (CD178) (29), or by agonistic antibodies induces apoptosis in sensitive cells (31, 36). The death-inducing signaling complex (DISC) is formed within seconds after CD95 stimulation (9). The DISC consists of oligomerized, probably trimerized CD95 receptors, the adaptor molecule FADD, two isoforms of procaspase-8 (procaspase-8a and -8b), procaspase-10, and c-FLIP_L/S/R (6, 19, 21, 25, 27). The interactions between molecules at the DISC are based on homotypic contacts. The death domain of the receptor interacts with the death domain of FADD, while the death effector domain (DED) of FADD interacts with the N-terminal tandem DEDs of procaspase-8 and -10 and c-FLIP_L/S/R.Two isoforms of procaspase-8 (procaspase-8a and procaspase-8b) were reported to be bound to the DISC (24). Both isoforms possess two tandem DEDs, as well as the catalytic subunits p18 and p10 (see Fig. ​Fig.1A).1A). Procaspase-8a contains an additional 2-kDa (15-amino-acid [aa]) fragment, which results from the translation of exon 9. This small fragment is located between the second DED and the large catalytic subunit, resulting in different lengths of procaspase-8a and -8b (p55 and p53 kDa), respectively.Open in a separate windowFIG. 1.A new 30-kDa protein is detected by the anti-caspase-8 MAb C15. (A) Scheme of procaspase-8 and its cleavage products. The binding sites of the anti-caspase-8 MAbs C5 and C15 are indicated. (B) The B-lymphoblastoid cell lines SKW6.4, Raji, and BJAB and the T-cell lines CEM, Jurkat 16, and caspase-8-deficient Jurkat (clone JI9.2) were stimulated with LZ-CD95L for the indicated times, followed by caspase-8 immunoprecipitation (C8-IP) using the anti-caspase-8 MAb C15 directed against the p18 subunit of procaspase-8. Western blotting of immunoprecipitates was performed using the anti-caspase-8 MAb C15 (**, Ig heavy chain; *, unspecific band). (C) SKW6.4 cells were stimulated with LZ-CD95L for different times, and procaspase-8 processing in total cellular lysates was analyzed by Western blotting using the anti-caspase-8 MAb C15. (D) B-lymphoblastoid BJAB cells were stimulated with LZ-TRAIL for different times, and procaspase-8 processing was analyzed as described for panel C. (E) Primary human T cells (day 6) were stimulated with LZ-CD95L, and procaspase-8 processing was analyzed as described for panel C (*, unspecific band).Activation of procaspase-8 is believed to follow an “induced-proximity” model in which high local concentrations and a favorable mutual orientation of procaspase-8 molecules at the DISC lead to their autoproteolytic processing (2, 3, 20). There is strong evidence from several in vitro studies that autoproteolytic activation of procaspase-8 occurs after oligomerization at the receptor complex (20). Furthermore, it has been shown that homodimers of procaspase-8 have proteolytic activity and that proteolytic processing of procaspase-8 occurs between precursor homodimers (3).Procaspase-8a/b (p55/p53) processing at the DISC has been described to involve two sequential cleavage steps (see Fig. ​Fig.1A).1A). This process is referred to as the “two-step model” (3, 17). The first cleavage step occurs between the two protease domains, and the second cleavage step takes place between the prodomain and the large protease subunit (see Fig. ​Fig.1A)1A) (15). During the first cleavage step, the cleavage at Asp³⁷⁴ generates the two subunits p43/p41 and p12. Both cleavage products remain bound to the DISC: p43/p41 by DED interactions and p12 by interactions with the large protease domain of p43/p41. The second cleavage step takes place at Asp²¹⁶ and Asp³⁸⁴, producing the active enzyme subunits p18, p10, and the prodomain p26/p24. As a result of procaspase-8 processing, the active caspase-8 heterotetramer p18₂-p10₂ is formed at the DISC. This heterotetramer is subsequently released into the cytosol, starting the apoptotic signaling cascade (14).Recent studies have shown that processing of procaspase-8 at the DISC is more complicated and can involve additional steps like the generation of a prolonged prodomain of procaspase-8, termed CAP3 (p27), that is quickly converted to p26 (see Fig. ​Fig.1A)1A) (7).In addition to its central role in death receptor-induced apoptosis, caspase-8 was reported to be required for proliferation of lymphocytes (12, 23). Recently caspase-8 was shown to be an important factor for NF-κB activation following T-cell receptor stimulation (28). The mechanism underlying the dual role of caspase-8 activity and its regulation is largely unknown.In the present study, we show that upon death receptor stimulation, p30 is formed by cleavage at Asp²¹⁰, a yet-unknown cleavage product of procaspase-8, which comprises the C terminus of procaspase-8. p30 turned out to be a key intermediate product in the course of procaspase-8 processing. Furthermore, we suggest that the p30-mediated activation of procaspase-8 plays an important role in the amplification of the death signal. Taken together, our findings provide a new mechanism of procaspase-8 activation and extend the current two-step cleavage model by an alternative activation pathway.     

Kinetic Analysis of Permeation of Mitochondria-Targeted Antioxidants Across Bilayer Lipid Membranes

Mitochondria-targeted antioxidants consisting of a quinone part conjugated with a lipophilic cation via a hydrocarbon linker were previously shown to prevent oxidative damage to mitochondria in vitro and in vivo. In the present work, we studied the permeation of a series of compounds of this type across a planar bilayer phospholipid membrane. For this purpose, relaxation of the electrical current after a voltage jump was measured. With respect to the characteristic time of the relaxation process reflecting the permeation rate, hydrophobic cations can be ranked in the following series: 10(plastoquinonyl) decylrhodamine 19 (SkQR1) > 10-(6'-plastoquinonyl) decyltriphenylphosphonium (SkQ1) > 10-(6'-methylplastoquinonyl) decyltriphenylphosphonium (SkQ3) > 10-(6'-ubiquinonyl) decyltriphenylphosphonium (MitoQ). Thus, the permeation rate increased with (1) an increase in the size of the hydrophobic cation and (2) an increase in hydrophobicity of the quinone moiety. SkQ1 containing plastoquinone was shown to be more permeable through the membrane compared to MitoQ containing ubiquinone, which might be the reason for more pronounced beneficial action of SkQ1 in vitro and in vivo. The above approach can be recommended for the search for new antioxidants or other compounds targeted to mitochondria.     

Effect of weak static and low-frequency alternating magnetic fields on the fission and regeneration of the planarian dugesia (Girardia) tigrina

The effect of weak static (DC) and alternating (AC) magnetic fields (MFs), as well as combined (AC/DC) collinear MFs on the intensity of morphogenesis processes in the planarian Dugesia (Girardia) tigrina has been studied. It was found that combined MFs produce a stimulating effect on the fission and regeneration of planarians. Both components of the combined MFs, the direct (DC) and the alternating (AC), are important in the realization of the effects of weak MFs. The practically complete absence of one of the components (DC) reverses the sign of the effect. It was shown that the presence of concomitant background MFs does not substantially influence the effects of combined MFs with a very small AC component (100 nT). The effect of the "zero" field is significant and comparable in magnitude with the effects of combined MFs at effective frequencies. Narrow zones of effective amplitudes (in the region of tens and hundreds of nT) of the AC component of the combined MFs, with the DC component close to the value of the geomagnetic field were found, which alternate with regions where the response of the biological object to the influence is absent.