Transposon-mediated targeted and specific knockdown of maternally expressed transcripts in the ascidian Ciona intestinalis.

Maternal mRNAs play crucial roles during early embryogenesis of ascidians, but their functions are largely unknown. In this study, we developed a new method to specifically knockdown maternal mRNAs in Ciona intestinalis using transposon-mediated transgenesis. We found that GFP expression is epigenetically silenced in Ciona intestinalis oocytes and eggs, and this epigenetic silencing of GFP was used to develop the knockdown method. When the 5' upstream promoter and 5' untranslated region (UTR) of a maternal gene are used to drive GFP in eggs, the maternal gene is specifically knocked down together with GFP. The 5' UTR of the maternal gene is the major element that determines the target gene silencing. Zygotic transcription of the target gene is unaffected, suggesting that the observed phenotypes specifically reflect the maternal function of the gene. This new method can provide breakthroughs in studying the functions of maternal mRNAs.

A novel treatment strategy for ovarian cancer based on immunization against zona pellucida protein (ZP) 3.

We tested the principle of treating malignant ovarian tumors by vaccination against their ectopically expressed protein, zona pellucida glycoprotein (ZP) 3, using as the experimental model the granulosa cell tumors that develop in transgenic mice expressing the simian virus 40 T-antigen under the inhibin-α promoter (inhα/Tag). We found high ZP3 expression in granulosa cell tumors of the transgenic mice, in human surface ovarian cancer and granulosa cell lines, and in human granulosa cell tumors and their metastases. Early preventive immunization (between 2 and 5.5 mo of age) of transgenic mice with recombinant human (rh) ZP3 prevented ovarian tumorigenesis, and delayed therapeutic immunization (between 4.5 and 7 mo) reduced weights of existing tumors by 86 and 75%, respectively (P<0.001), compared to vehicle-treated control mice. No objective side effects of the immunizations were observed. Liver metastases were found in nontreated/vehicle-treated controls (n=7/39), but none following active rhZP3 immunizations (n=0/36; P<0.05). Immunization with rhZP3 was highly effective, as demonstrated by the induction of anti-ZP3 antibodies, as well as proliferative responses to the ZP3 antigen. These results signal rhZP3 immunization as a novel strategy to be developed for the immunotherapy of ovarian granulosa cell tumors, as well as for that of other malignancies that may express ZP3.

Scavenger receptor mediates systemic RNA interference in ticks.

RNA interference is an efficient method to silence gene and protein expressions. Here, the class B scavenger receptor CD36 (SRB) mediated the uptake of exogenous dsRNAs in the induction of the RNAi responses in ticks. Unfed female Haemaphysalis longicornis ticks were injected with a single or a combination of H. longicornis SRB (HlSRB) dsRNA, vitellogenin-1 (HlVg-1) dsRNA, and vitellogenin receptor (HlVgR) dsRNA. We found that specific and systemic silencing of the HlSRB, HlVg-1, and HlVgR genes was achieved in ticks injected with a single dsRNA of HlSRB, HlVg-1, and HlVgR. In ticks injected first with HlVg-1 or HlVgR dsRNA followed 96 hours later with HlSRB dsRNA (HlVg-1/HlSRB or HlVgR/HlSRB), gene silencing of HlSRB was achieved in addition to first knockdown in HlVg-1 or HlVgR, and prominent phenotypic changes were observed in engorgement, mortality, and hatchability, indicating that a systemic and specific double knockdown of target genes had been simultaneously attained in these ticks. However, in ticks injected with HlSRB dsRNA followed 96 hours later with HlVg-1 or HlVgR dsRNAs, silencing of HlSRB was achieved, but no subsequent knockdown in HlVgR or HlVg-1 was observed. The Westernblot and immunohistochemical examinations revealed that the endogenous HlSRB protein was fully abolished in midguts of ticks injected with HlSRB/HlVg-1 dsRNAs but HlVg-1 was normally expressed in midguts, suggesting that HlVg-1 dsRNA-mediated RNAi was fully inhibited by the first knockdown of HlSRB. Similarly, the abolished localization of HlSRB protein was recognized in ovaries of ticks injected with HlSRB/HlVgR, while normal localization of HlVgR was observed in ovaries, suggesting that the failure to knock-down HlVgR could be attributed to the first knockdown of HlSRB. In summary, we demonstrated for the first time that SRB may not only mediate the effective knock-down of gene expression by RNAi but also play essential roles for systemic RNAi of ticks.

Evidence for the inhibition of fertilization in vitro by anti-ZP3 antisera derived from DNA vaccine.

Previously we have found that DNA vaccine, pCMV4-rZPC' can generate specific antibodies against rabbit ZPC (amino acid 263-415, rZPC'), which binds to ovarian ZP and leads to a significant reduction of fertility in vivo. The purpose of this study was to evaluate the effect of antisera from pCMV4-rZPC(')-immunized mice on sperm-oocyte interaction in vitro. The effect of antisera from DNA vaccine-immunized mice on fertilization and early embryonic development was studied using an in vitro fertilization system. The results showed that the antisera supplemented in fertilization medium (10%, v/v) significantly decreased the rate of fertilization compared to that of control groups (P<0.05); whereas the antisera showed no significant effect on the rate of fertilization when ZP-free eggs were used. Moreover, the antisera pre-neutralized with mouse soluble zona pellucida lost the capacity to inhibit fertilization when compared with that of control groups. In addition, the antisera showed no detrimental effect on early developmental potential of mouse embryos in vitro. Taken together, our study provided herein direct evidence showing that antisera generated by DNA vaccine can block sperm-egg recognition during fertilization via targeting the oocyte ZP proteins.

Towards a ZP-based contraceptive for marsupials: comparative analysis and developmental expression of marsupial ZP genes.

Fertility control in the form of a zona pellucida (ZP)-based immunocontraceptive has shown potential as a humane form of control for overabundant marsupials including the brushtail possum and macropods. Further refinement and development of a ZP-based vaccine requires detailed knowledge of the protein structure and expression in order to ensure maximum efficacy and specificity. Sequencing and comparative analysis of the ZP3 protein from three marsupial orders in this study found a high overall level of conservation; within order Diprotodontia, the ZP3 protein is 86.9-98.9% identical. ZP3 identity falls to 56.6-57.2%, when the grey, short-tailed opossum (a Didelphimorphian) is compared to dasyurid and diprotodontan marsupials. This is similar to its amino acid identity with ZP3 from eutherian species (50.7-52.8%). Comparison of a 21 amino acid epitope in marsupial ZP3 that has shown contraceptive effects, reveals 95-100% identity between the four macropodid species, 81-86% amino acid identity between brushtail possum and the macropods and 67-71% identity between the diprotodontans and the fat-tailed dunnart (a dasyurid). This is comparable to the level of identity between related eutherian mammals. The expression pattern of three ZP genes during brushtail possum and tammar wallaby pouch young development was examined by RT-PCR. This analysis of ZP gene expression has confirmed that ZP mRNA transcription begins in the ovary during pouch young development by about 51 days of age. The presence of ZP transcripts at this stage in pouch young development suggests that marsupial ZP gene transcription begins before the onset of follicular development.

The functional analysis of Type I postplasmic/PEM mRNAs in embryos of the ascidian Halocynthia roretzi.

Maternal factors, such as a muscle determinant macho-1 mRNA that is localized to the posterior-vegetal cortex (PVC) of fertilized ascidian eggs, are crucial for embryonic axis formation and cell fate specification. Maternal mRNAs that show an identical posterior localization pattern to that of macho-1 in eggs and embryos are called Type I postplasmic/PEM mRNAs. We investigated the functions of five of the nine Type I mRNAs so far known in Halocynthia roretzi: Hr-Wnt-5, Hr-GLUT, Hr-PEM3, Hr-PEN1, and Hr-PEN2. Suppression of their functions with specific antisense morpholino oligonucleotides (MOs) had effects on the formation of various tissues: Hr-Wnt-5 on notochord, muscle, and mesenchyme, although zygotic function of Hr-Wnt-5 is responsible for notochord formation; Hr-GLUT on notochord, mesenchyme, and endoderm; and Hr-PEN2 on muscle, mesenchyme, and endoderm. On the other hand, Hr-PEM3 and Hr-PEN1 MOs seemed to have no effect. We conclude that the functions of at least some localized maternal Type I postplasmic/PEM mRNAs are necessary for early embryonic patterning in ascidians.

Corticosterone impairs MHC class I antigen presentation by dendritic cells via reduction of peptide generation.

The presentation of viral peptide-MHC class I complexes by antigen presenting cells, such as dendritic cells (DCs), is obligatory for the generation of antiviral effector and memory CD8(+) cytotoxic T lymphocyte (CTL) responses. Prolonged psychological stress is immunosuppressive and undermines primary and memory CTL-mediated antiviral immunity; however, the mechanisms involved are unknown. Using a panel of novel reagents and techniques, we quantitatively measured the effect of the stress-induced hormone corticosterone (CORT) on the efficiency of DCs to process and present virally expressed antigen, characterized the conditions for this CORT-mediated effect, and delineated the components of the MHC class I pathway that were affected. We found that physiologically relevant levels of CORT, prior to infection and acting via the glucocorticoid receptor, suppressed the formation of peptide-MHC class I complexes on the surface of infected DCs. We further showed that this suppression of peptide-MHC class I complexes is via the action of CORT on elements of the class I pathway upstream from TAP that are involved in the generation of antigenic peptides. This CORT-mediated suppression of peptide-class I complexes on DCs also resulted in a marked reduction of their ability to activate a specific T cell hybridoma. These findings offer a mechanism contributing to the stress-induced suppression of host defenses against viral diseases and have implications for the efficacy of antiviral vaccines. At the most fundamental cellular level, this impairment of antigen processing has implications for the regulation of protein degradation in all cells, which is critical to many aspects of immune function.

The role of T cell antagonism and original antigenic sin in genetic immunization.

To counter highly mutable pathogens like HIV-1, a number of vaccines are being developed to deliver multiple mutant forms of viral Ags to provoke multivalent antiviral CTLs. However, it is uncertain whether such multiple mutant epitope vaccines will generate the diverse CTL responses desired or will instead create immune interference. To characterize the role of immune interference by mutant epitopes in this process, we have tested a "worst case" scenario in which the immunodominant epitope of OVA (SIINFEKL) and its in vitro TCR antagonist (SIINFEDL) have been used to genetically immunize C57BL/6 mice. We demonstrate here that sequential delivery of these mutant epitopes provokes original antigenic sin in CD8 T cells as demonstrated by attenuation of CTLs, intracellular IFN-gamma production, and MHC I peptide-tetramer staining. By contrast, simultaneous exposure of the immune system to this agonist/antagonist pair not only fails to generate T cell antagonism in vivo, but also avoids original antigenic sin. These observations suggest that simultaneous immunization with vaccines containing mutant epitopes, even T cell antagonists, can indeed generate a diverse array of T cell responses and that at least some immune interference can be avoided by delivering mutant Ags to the immune system simultaneously.

Chromosome condensation in pig oocytes: lack of a requirement for either cdc2 kinase or MAP kinase activity.

In this study, butyrolactone I (BL I), a potent and specific inhibitor of cyclin-dependent kinases (cdk), is shown to inhibit germinal vesicle breakdown (GVBD) in pig oocytes. Oocytes treated with 100 microM BL I were arrested in the germinal vesicle (GV)-stage and displayed low activity of cdc2 kinase and MAP kinase. Nevertheless, chromosome condensation occurred and highly condensed bivalents were seen within an intact GV after a 24-hr culture in the presence of BL I. The inhibitory effect of BL I on MAP kinase activation during culture was likely mediated through a cdk-dependent pathway, since MAP kinase activity present in extracts derived from metaphase II eggs was not inhibited by BL I. The block of GVBD could be released by treating oocytes with okadaic acid (OA), an inhibitor of type 1 and 2A phosphatases; 82% of the oocytes treated with the combination of OA/BL I underwent GVBD, and MAP kinase became activated, while cdc2 kinase remained inhibited. These results suggest that both chromosome condensation and GVBD could occur without activation of cdc2 kinase, whereas an increase in MAP kinase activity may be a requisite for GVBD in pig oocytes in conditions when cdc2 kinase activation is blocked by BL I.

Evidence for the involvement of a Src-related tyrosine kinase in Xenopus egg activation.

Recently, we have purified a Src-related tyrosine kinase, named Xenopus tyrosine kinase (Xyk), from oocytes of Xenopus laevis and found that the enzyme is activated within 1 min following fertilization [Sato et al. (1996) J. Biol. Chem. 271, 13250-13257]. A concomitant translocation of a part of the activated enzyme from the membrane fraction to the cytosolic fraction was also observed. In the present study, we show that parthenogenetic egg activation by a synthetic RGDS peptide [Y. Iwao and T. Fujimura, T. (1996) Dev. Biol. 177, 558-567], an integrin-interacting peptide, but not by electrical shock or the calcium ionophore A23187 causes the kinase activation, tyrosine phosphorylation, and translocation of Xyk. A synthetic tyrosine kinase-specific inhibitor peptide was employed to analyze the importance of the Xyk activity in egg activation. We found that the peptide inhibits the kinase activity of purified Xyk at IC50 of 8 microM. Further, egg activation induced by sperm or RGDS peptide but not by A23187 was inhibited by microinjection of the peptide. In the peptide-microinjected eggs, penetration of the sperm nucleus into the egg cytoplasm and meiotic resumption in the egg were blocked. Indirect immunofluorescence study demonstrates that Xyk is exclusively localized to the cortex of Xenopus eggs, indicating that Xyk can function in close proximity to the sperm-egg or RGDS peptide-egg interaction site. Taken together, these data suggest that the tyrosine kinase Xyk plays an important role in the early events of Xenopus egg activation in a manner independent or upstream of calcium signaling.

Specific proteolytic cleavages limit the diversity of the pool of peptides available to MHC class I molecules in living cells.

MHC class I molecules display peptides selected from a poorly characterized pool of peptides available in the endoplasmic reticulum. We analyzed the diversity of peptides available to MHC class I molecules by monitoring the generation of an OVA-derived octapeptide, OVA257-264 (SL8), and its C-terminally extended analog, SL8-I. The poorly antigenic SL8-I could be detected in cell extracts only after its conversion to the readily detectable SL8 with carboxypeptidase Y. Analysis of extracts from cells expressing the minimal precursor Met-SL8-I by this method revealed the presence of SL8/Kb and the extended SL8-I/Kb complexes, indicating that the peptide pool contained both peptides. In contrast, cells expressing full length OVA generated only the SL8/Kb complex, demonstrating that the peptide pool generated from the full length precursor contained only a subset of potential MHC-binding peptides. Deletion analysis revealed that SL8-I was generated only from precursors lacking additional C-terminal flanking residues, suggesting that the generation of the C terminus of the SL8 peptide involves a specific endopeptidase cleavage. To investigate the protease responsible for this cleavage, we tested the effect of different protease inhibitors on the generation of the SL8 and SL8-I peptides. Only the proteasome inhibitors blocked generation of SL8, but not SL8-I. These findings demonstrate that the specificities of the proteases in the Ag-processing pathway, which include but are not limited to the proteasome, limit the diversity of peptides available for binding by MHC class I molecules in the endoplasmic reticulum.

Inhibition of protein synthesis in frog (Xenopus laevis) egg extracts by an antibody against phosphatidylinositol 4,5-bisphosphate.

The antibody kt10, which is directed against the phospholipid PtdIns(4,5)P2, inhibits protein synthesis when added to cytosolic extracts prepared from frog eggs. Addition of stable analogues of diacylglycerol and Ins(1,4,5)P3 failed to rescue the inhibition of translation, suggesting that the effect of the antibody was not to block hydrolysis of PtdIns(4,5)P2. Neomycin, which also binds PtdIns(4,5)P2, produced a similar reduction in protein-synthesis levels in the extract system, supporting the idea that it is the interaction of the antibody with PtdIns(4,5)P2 that is producing the effect.

Role of the N terminus in RNase A homologues: differences in catalytic activity, ribonuclease inhibitor interaction and cytotoxicity.

A number of biochemical properties differ dramatically among homologues within the pancreatic ribonuclease superfamily. Human pancreatic ribonuclease (hRNase) has high enzyme activity, extreme sensitivity to ribonuclease inhibitor (RI) and is non-toxic, whereas a homologous RNase from frog eggs, called onconase, has much lower enzyme activity, is not sensitive to RI and is cytotoxic to cancer cell lines and animals. To explore the structural basis of these differences among members in the RNAse family we synthesized genes for onconase, hRNase, a mutant onconase (K9Q) and onconase-hRNase N-terminal hybrids and expressed the proteins in Escherichia coli with final yields of 10 to 50 mg per liter of culture after purification. A recombinant version of onconase with an N-terminal methionine instead of the native pyroglutamyl residue had decreased cytotoxicity and enzyme activity. Cleavage of the recombinant onconase Met-1 residue, and cyclization of the Gln1 residue to reform the pyroglutamyl N terminus, reconstituted cytotoxicity and enzyme activity. Thus a unique role of the pyroglutamyl residue in the active site of amphibian RNases is indicated. Replacement of one to nine residues of onconase with the homologous residues of hRNase increased the enzymatic activity against most of the substrates tested with a simultaneous shift in the enzyme specificity from high preference for poly(U) to slight preference for poly(C). Cytotoxicity of the chimera decreased, dissociating cytotoxicity from enzymatic activity. The molecular basis for the low binding affinity of onconase for RI has been examined experimentally with the recombinant RNases and by fitting onconase and RNase A structures to the coordinates from the recently published RNase A-RI complex.

The crystal and molecular structure of the third domain of silver pheasant ovomucoid (OMSVP3).

OMSVP3 and OMTKY3 (third domains of silver pheasant and turkey ovomucoid inhibitor) are Kazal-type serine proteinase inhibitors. They have been isomorphously crystallized in the monoclinic space group C2 with cell dimensions of a = 4.429 nm, b = 2.115 nm, c = 4.405 nm, beta = 107 degrees. The asymmetric unit contains one molecule corresponding to an extremely low volume per unit molecular mass of 0.0017 nm3/Da. Data collection was only possible for the OMSVP3 crystals. Orientation and position of the OMSVP3 molecules in the monoclinic unit cells were determined using Patterson search methods and the known structure of the third domain of Japanese quail ovomucoid (OMJPQ3) [Papamokos, E., Weber, E., Bode, W., Huber, R., Empie, M. W., Kato, I. and Laskowski, M., Jr (1982) J. Mol. Biol. 158, 515-537]. The OMSVP3 structure has been refined by restrained crystallographic refinement yielding a final R value of 0.199 for data to 0.15 nm resolution. Conformation and hydrogen-bonding pattern of OMSVP3 and OMJPQ3 are very similar. Large deviations occur at the NH2 terminus owing to different crystal packing, and at the C terminus of the central helix, representing an intrinsic property and resulting from amino acid substitutions far away from this site. The deviation of OMSVP3 from OMTKY3 complexed with the Streptomyces griseus protease B is very small [Fujinaga, M., Read, R. J., Sielecki, A., Ardelt, W., Laskowski, M., Jr and James, M. N. G. (1982) Proc. Natl Acad. Sci. USA, 79, 4868-4872].

Periodate inactivation of ovotransferrin and human serum transferrin.

Azari and Phillips (Azari, P., and Phillips, J. L. 1970 Arch. Biochem. Biophys. 138, 32-38) reported that periodate treatment of iron-free ovotransferrin causes a rapid loss of iron-binding activity and an oxidation of 3 to 5 tyrosines and 1 tryptophan. Rapid inactivation and loss of tyrosine in ovotransferrin has been confirmed, and the work extended to human serum transferrin and effects of denaturing concentrations of urea. Extensive (> 80%) inactivations of both ovotransferrin and human serum transferrin were observed when approximately 4 tyrosines were destroyed. Amino acid analysis and 360-MHz 1H NMR spectra confirmed that tyrosines are the only residues rapidly oxidized; the correlation of tyrosine loss with the loss of iron-binding activity suggests strongly that the tyrosines involved are those that function as ligands to metal ions bound to the protein. NMR spectra also showed that periodate oxidation causes local changes of structure in ovotransferrin (presumably at the metal-binding sites) but does not grossly alter the conformation. The addition of 5 to 8 M urea greatly retarded the inactivation and losses of tyrosine.