Immunogenicity of Concentrated and Purified Inactivated Avian Influenza Vaccine Formulation.

Avian influenza (AI) H9N2 is a low pathogenic virus subtype belonging to Orthomyxoviridae family. Given the prevalence of this subtype as an infectious agent in poultry industry, special attention has been always directed toward the development of vaccine production against this infection. The vaccine of this infection is produced by killing the virus and using a mixture of inactivated antigen and oil phase. Egg-based viral antigens have high levels of unwanted proteins that may adversely affect the vaccine formulation. In addition, it is required to raise the antigen concentration for the production of combination vaccines, especially in low doses. This underscores the need to the improvement of the downstream purification process and concentration of antigens. The optimization of downstream processing would decrease the cost of vaccine procurement and maintenance. Regarding this, the present study was conducted to evaluate a downstream procedure for the concentration and purification of avian influenza virus (H9N2) and investigate the immunogenicity of the vaccine containing these antigens. To this end, after harvesting and clarifying virus-containing allantoic fluid, it was concentrated and purified using ultrafiltration and chromatography, respectively. The concentrated and purified samples were checked for their ovalbumin level and emulsified with oil adjuvant to access their immunogenicity. The results showed that one dose of both formulated antigens (i.e., concentrated and purified) was effective in raising the immune response in the vaccinated chicks for a long time. The applied formulation had a one-year stability in the refrigerator. Furthermore, the concentrated antigen showed a high hemagglutination activity through a year when storing in the refrigerator. Based on the findings, the optimization of downstream process of influenza (H9N2) vaccine production and use of new technologies could be considered in the large-scale preparation of a sustainable vaccine without any unwanted risk factors.

Is there a rationale for neuroprotection against dopamine toxicity in Parkinson's disease?

Parkinson's disease is a progressive neurological disease caused by rather selective degeneration of the dopaminergic neurons in the substantia nigra. Though subject to intensive research, the etiology of this nigral loss is still undetermined and treatment is basically symptomatic. The current major hypothesis is that nigral neuronal death in PD is due to excessive oxidative stress generated by auto and enzymatic oxidation of the endogenous neurotransmitter dopamine (DA), the formation of neuromelanin (NM) and the presence of a high concentration of iron. In this review article although we concisely describe the effects of NM and iron on neuronal survival, we mainly focus on the molecular mechanisms of DA-induced apoptosis. DA exerts its toxic effects through its oxidative metabolites either in vitro or in vivo The oxidative metabolites then activate a very intricate web of signals, which culminate in cell death. The signal transduction pathways and genes, which are associated with DA toxicity are described in detail.

Molecular biology of dopamine-induced apoptosis : possible implications for Parkinson's disease.

The causes for the highly selective loss of dopaminergic neurons in the substantia nigra pars compacta in Parkinson's disease (PD) are still unknown. However, a major advance has been recently made with the introduction of the concept of apoptosis as the route leading this specific neuronal population to degeneration. Apoptosis, or programmed cell death (PCD), is an active, controlled program inherent in every living cell. Upon receiving certain signals, cells that are destined to die undergo a highly characteristic process of "suicide." This process consists of massive biochemical and morphological alterations, including cell shrinkage, loss of cell-to-cell contacts, blebbing of cell membranes, cytoskeletal rearrangements, and DNA condensation and fragmentation. It culminates in cell conversion to membrane-bound particles (apoptotic bodies) that are ready to be digested by neighboring macrophages (1-3).

Induction of neuronal apoptosis by Semaphorin3A-derived peptide.

Collapsin-1/Semaphorin3A (Sema3A) belongs to the secreted type III semaphorins family of axon guidance molecules with chemorepulsive activity, and is suggested to play a major role in navigating axonal networks throughout development into their correct destinations. We have previously shown that semaphorins are mediators of neuronal apoptosis and can induce neuronal death in the absence of any other apoptotic trigger. We report here that exposure of neuronal cells to a small conserved peptide derived from Sema3A initiates an apoptotic death process. Administration of this peptide to cultured chick sympathetic and mouse cerebellar granule neurons caused a marked shrinkage of their axonal network and cell death, which was characterized as apoptotic, based on nuclear staining. Attenuation of neuronal cell death was obtained by treatment with antioxidants and by vascular endothelial growth factor. Survival of neurons exposed to this peptide increased by co-treatment with caspase inhibitors. Induction of apoptosis was specific to neuronal cells, similarly to that induced by the full-length Sema3A protein. Our findings therefore suggest active participation of this conserved Sema3A-derived peptide in semaphorin-induced neuronal death process.

Levodopa--an exotoxin or a therapeutic drug?

Auto-oxidation of levodopa generates toxic metabolites, such as free radicals, semiquinones and quinones. In vitro, levodopa is a powerful toxin that is lethal to cultures of neurones. This raises the concern that levodopa may also be toxic in vivo, and that chronic treatment with levodopa could induce further damage to nigrostriatal neurones in patients with Parkinson's disease, accelerating the natural predetermined rate of disease progression. Although a few animal studies have shown that chronic levodopa may be toxic in vivo, most others report that it is not. The few available clinical studies also indicate that the course of Parkinson's disease is not accelerated by chronic systemic treatment with levodopa.

Involvement of T-complex protein-1delta in dopamine triggered apoptosis in chick embryo sympathetic neurons.

The neurotransmitter dopamine (DA) is capable of inducing apoptosis in post-mitotic sympathetic neurons via its oxidative metabolites. The differential display method was applied to cultured sympathetic neurons in an effort to detect genes whose expression is transcriptionally regulated during the early stages of DA-triggered apoptosis. One of the up-regulated genes was identified as the chick homologue to T-complex polypeptide-1delta (TCP-1delta), a member of the molecular chaperone family of proteins. Each chaperone protein is a complex of seven to nine different subunits. A full-length clone of 1.9 kilobases was isolated containing an open reading frame of 536 amino acids with a predicted molecular weight of 57,736. Comparison with the mouse TCP-1delta revealed 78 and 91% homology on the DNA and protein levels, respectively. Northern blot analysis disclosed a steady and significant increase in mRNA levels of TCP-1delta after DA administration, reaching a peak between 4 and 9 h and declining thereafter. Induction of the TCP-1delta protein levels was also observed as a function of DA treatment. Overexpression of TCP-1delta in sympathetic neurons accelerated DA-induced apoptosis; inhibition of TCP-1delta expression in these neurons using antisense technology significantly reduced DA-induced neuronal death. These findings suggest a functional role for TCP-1delta as a positive mediator of DA-induced neuronal apoptosis.

The molecular mechanism of dopamine-induced apoptosis: identification and characterization of genes that mediate dopamine toxicity.

Parkinson's disease (PD) is a progressive neurological disorder caused by rather selective degeneration of the dopaminergic (DA) neurons in the substantia nigra. Though subject to intensive research, the etiology of this nigral neuronal loss is still enigmatic and treatment is basically symptomatic. The current major hypothesis suggests that nigral neuronal death in PD is due to excessive oxidative stress generated by auto- and enzymatic oxidation of the endogenous neurotransmitter dopamine (DA), the formation of neuromelanin and presence of high concentrations of iron. We have found that DA toxicity is mediated through its oxidative metabolites. Whereas thiol-containing antioxidants provided marked protection against DA toxicity, ascorbic acid accelerated DA-induced death. Using the differential display approach, we sought to isolate and characterize genes whose expression is altered in response to DA toxicity. We found an upregulation of the collapsin response mediator protein (CRM) and TCP-1delta in sympathetic neurons, which undergo dopamine-induced apoptosis. The isolation of these genes led us to examine the expression and activity of CRM and TCP-1delta related genes. Indeed, we found a significant induction of mRNAs of the secreted collapsin-1 and the mitochondrial stress protein HSP60. Antibodies directed against collapsin-1 provided marked and prolonged protection of several neuronal cell types from dopamine-induced apoptosis. In a parallel study, using antisense technology, we found that inhibition of TCP-1delta expression significantly reduced DA-induced neuronal death. These findings suggest a functional role for collapsin-1 and TCP-1delta as positive mediators of DA-induced neuronal apoptosis.

Semaphorins as mediators of neuronal apoptosis.

Shrinkage and collapse of the neuritic network are often observed during the process of neuronal apoptosis. However, the molecular and biochemical basis for the axonal damage associated with neuronal cell death is still unclear. We present evidence for the involvement of axon guidance molecules with repulsive cues in neuronal cell death. Using the differential display approach, an up-regulation of collapsin response mediator protein was detected in sympathetic neurons undergoing dopamine-induced apoptosis. A synchronized induction of mRNA of the secreted collapsin-1 and the intracellular collapsin response mediator protein that preceded commitment of neurons to apoptosis was detected. Antibodies directed against a conserved collapsin-derived peptide provided marked and prolonged protection of several neuronal cell types from dopamine-induced apoptosis. Moreover, neuronal apoptosis was inhibited by antibodies against neuropilin-1, a putative component of the semaphorin III/collapsin-1 receptor. Induction of neuronal apoptosis was also caused by exposure of neurons to semaphorin III-alkaline phosphatase secreted from 293EBNA cells. Anti-collapsin-1 antibodies were effective in blocking the semaphorin III-induced death process. We therefore suggest that, before their death, apoptosis-destined neurons may produce and secrete destructive axon guidance molecules that can affect their neighboring cells and thus transfer a "death signal" across specific and susceptible neuronal populations.

Levodopa toxicity and apoptosis.

Many in vitro studies have shown that levodopa is a potent toxin which is lethal to various cultured neuronal and non-neuronal cells. The in vitro toxicity of levodopa is linked mainly to its auto-oxidation, which generates a variety of harmful free radical species including superoxide, hydrogen peroxide, and hydroxyl radicals, and also semiquinones and quinones produced via the dopa-melanin metabolic route. Such toxic effects of levodopa can be blocked by co-treatment with antioxidants, particularly thiol-containing compounds. Several studies have shown that levodopa kills cells by triggering apoptosis, an active, intrinsic cell suicide program. Exposure of cultured neurons to levodopa induced the characteristic apoptotic cascade, including cell shrinkage, membrane blebbing, and nuclear and DNA fragmentation. Although levodopa is extremely toxic in vitro, there is no evidence that it damages nigrostriatal dopaminergic neurons in vivo in experimental animals and in patients with Parkinson's disease (PD). Likewise, although there is some evidence for the occurrence of apoptosis in the parkinsonian substantia nigra, it is not known whether levodopa administration is capable of inducing or accelerating programmed cell death of residual pigmented nigral neurons in PD.

Expression of cell cycle-related genes during neuronal apoptosis: is there a distinct pattern?

An emerging hypothesis considers the process of neuronal apoptosis as a consequence of unscheduled and unsynchronized induction of cell cycle mediators. Induction of several cell cycle genes precedes neuronal apoptosis and may be involved in determination of cell fate. We have now characterized changes in expression of cell cycle genes during apoptosis induced by oxidative stress in chick post-mitotic sympathetic neurons. Induction of cyclin B occurred prior to the commitment of neurons to both dopamine- and peroxide-triggered apoptosis. Both the neuronal death and the rise in cyclin B were inhibited by antioxidant treatment, suggesting a functional role for cyclin B induction during neuronal apoptosis. Induction of the cyclin dependent kinase CDK5 protein coincided with the time point when neurons were irreversibly committed to die. Expression of other cell cycle mediators such as cyclin D1 and the cyclin dependent kinases CDC2 and CDK2 was undetected and not induced by exposure to oxidative stress. Comparative analysis of the profile of cell cycle mediators induced during neuronal apoptosis of different neuronal cell populations revealed no distinct pattern of events. There are no cell cycle stage-specific mediators that are ultimately stimulated during neuronal apoptosis, suggesting that multiple pathways of re-activating the dormant cell-cycle, converge to determine entry into apoptosis. Nevertheless, the existence of some cell cycle mediators, that were not reported so far to be induced in post mitotic neurons during oxidative stress, substantiate them as part of the strong differentiating forces.

Two waves of cyclin B and proliferating cell nuclear antigen expression during dopamine-triggered neuronal apoptosis.

The neurotransmitter dopamine is capable of inducing apoptosis in postmitotic sympathetic neurons via its oxidative metabolites. To detect genes whose expression is transcriptionally regulated during the early stages of dopamine-triggered apoptosis, we applied the differential display method to cultured sympathetic neurons. One of the up-regulated genes was identified as cyclin B2, which exhibited two waves of induction and destruction, both at the mRNA and protein levels, resembling the sequential oscillations typical of two successive mitotic events in proliferating cells. The time window between the two waves was characterized by a change in expression of other cell-cycle stage-specific genes, and oscillations in proliferating cell nuclear antigen and alterations in cyclin A were observed. Cyclin D1 and cyclin-dependent kinases were undetected and no sign of active DNA synthesis could be observed, indicating that activation of cell-cycle components is incomplete. In comparison with a normal cell cycle, temporal expression profile of these mediators was unsynchronized. Whereas the first wave of cell-cycle changes occurred prior to the commitment of the cells to the death process and could be tolerated by the cells, the second wave of changes coincided with the death commitment point. Our findings indicate that inappropriate and incomplete activation of some cell cycle-related genes in postmitotic neurons occurs during dopamine-triggered neuronal apoptosis.

Levodopa induces apoptosis in cultured neuronal cells--a possible accelerator of nigrostriatal degeneration in Parkinson's disease?

Apoptosis is an active, intrinsic cell suicide program. We recently suggested that it may have a role in the death of nigrostriatal dopaminergic neurons in Parkinson's disease (PD). We now report that levodopa, the current major therapy for PD, is a potent inducer of apoptosis in cultured postmitotic chick sympathetic neurons. Levodopa, in a concentration range of 0.01-0.3 mM, caused the characteristic apoptotic cascade of cell shrinkage, massive membrane blebbing, and nuclear fragmentation, as evident by nuclear flow cytometry and fluorescence microscopy. Levodopa-induced apoptosis was inhibited by antioxidants, indicating that it may be mediated by autooxidation-reactive species. Levodopa treatment for PD may therefore constitute an additional challenge for the defective apoptosis-inhibiting systems in the nigrostriatal neurons. Despite reassuring data from some, but not all, previous studies, these findings suggest that the possible in vivo toxic effects of levodopa on the survival of the remaining nigral neurons should be further explored.

Modulation of control mechanisms of dopamine-induced apoptosis--a future approach to the treatment of Parkinson's disease?

The cause for the progressive and selective degeneration of the dopaminergic (DA) nigrostriatal neurons in Parkinson's disease (PD) is still unknown. We suggest a novel approach, that links this neuronal degenerative process to inappropriate triggering of apoptosis, an active, controlled program of cellular self destruction, by excess oxidative stress mediated by DA metabolism. In support of this concept, we found that DA, the endogenous neurotransmitter, is capable of initiating apoptosis in cultured, postmitotic chick sympathetic neurons, an observation further extended to other cellular systems (PC-12 cells, cerebellar granular cells, thymocytes, splenocytes). In comparing the relative apoptosis-triggering potency of other mononamine neurotransmitters, DA was found to be the most active, whereas norepinephrine and serotonin had a moderate and a mild effects, respectively. This grading can be correlated with the relative involvement of the relevant neuronal systems (i.e., substantia nigra, locus ceruleus and raphe nuclei) in PD. We therefore hypothesize that neuronal degeneration in PD may be caused, at least in part, by a failure, either inherited or acquired, in cellular control systems of apoptosis, that may normally restrain the lethal potential of these endogenous neuro-transmitters and their potentially-toxic oxidation products. We therefore point at apoptosis-control systems as a critical scene of events, where the fate of nigrostriatal neurons is ultimately determined, and whose modulation may yield attenuation of the neuronal degenerative process. In support of this concept, we found that vector-driven stable expression of the proto-oncogene bcl-2, an inhibitor of apoptosis, can exert powerful cellular protection against DA toxicity in rat pheochromocytoma PC-12 cells. Furthermore, cell extracts from bcl-2-expressing cells were found to markedly inhibit in vitro oxidation of DA and production of DA-melanin. We also found that expression of bcl-2 can inhibit the decrease in intracellular reduced thiol (-SH) groups which we observed following exposure to DA. Research of the bcl-2 system and associated control mechanisms of apoptosis, possibly acting in association with intra-cellular anti-oxidant pathways, may therefore lead to novel therapeutic approaches for neuroprotection in PD.

Induction of mitosis-related genes during dopamine-triggered apoptosis in sympathetic neurons.

It was suggested that neuronal degeneration in Parkinson's Disease (PD) is linked to dopamine (DA) toxicity. Dopamine has been shown to induce programmed cell death in both neuronal and non-neuronal cell types. We examined the molecular changes associated with dopamine-triggered apoptosis in sympathetic neurons using the differential display approach, and isolated 14 different DA responsive genes whose expression is altered during the early stages of the apoptotic process. Nine of these genes are upregulated and five are downregulated in response to DA exposure. Two of the upregulated genes were identified as cyclin B2 and a chicken homologue of chaperonin, a member of the heat shock protein family. Total increase in mRNA expression of both genes after 12 hours of exposure to DA was 40%. These two genes participate in cell cycle control and are specifically involved in determining entry of dividing cells into mitosis. Upregulation of mitosis-related genes in postmitotic sympathetic neurons undergoing apoptosis, may be indicative of an abortive attempt of these neurons to re-enter the cell cycle prior to their death. Possible implications to neuronal degeneration in PD are discussed.

The proto-oncogene Bcl-2 inhibits cellular toxicity of dopamine: possible implications for Parkinson's disease.

It is currently believed that excessive oxidant stress induced by metabolism of dopamine (DA), plays a major role in the pathogenesis of the selective nigrostriatal neuronal loss in Parkinson's disease. We recently showed that the neurotransmitter DA, in physiological concentrations, is capable of initiating apoptosis in cultured, post-mitotic sympathetic neurons. Bcl-2 is a proto-oncogene that blocks apoptosis. We now report that Bcl-2 is a powerful inhibitor of DA toxicity in PC-12 pheochromocytoma cells. We induced stable expression of Bcl-2 in PC-12 cells by transfection with recombinant pCMV5 expression vector, containing mouse bcl-2 (coding-sequence) cDNA. Cells expressing Bcl-2 manifested marked resistance to otherwise lethal (300 uM) in vitroconcentrations of DA. This protective effect was reflected in the trypan-blue test of cell survival, 3 H-thymidine incorporation and inhibition of the characteristic apoptotic morphologic alterations in scanning electron microscopic studies. Bcl-2 and associated control systems of apoptosis may have an important physiological role in restraining the apop-tosis-triggering potential of DA in nigrostriatal neurons. This novel field of research may yield insights into the pathogenesis of Parkinson's disease and lead to development of novel therapeutic approaches.

Modification of the pH profile and tetrabenazine sensitivity of rat VMAT1 by replacement of aspartate 404 with glutamate.

Vesicular monoamine transporters (VMAT) catalyze transport of serotonin, dopamine, epinephrine, and norepinephrine into subcellular storage organelles in a variety of cells. Accumulation of the neurotransmitter depends on the proton electrochemical gradient (Delta micro H+) across the organelle membrane and involves VMAT-mediated exchange of two lumenal protons with one cytoplasmic amine. Mutagenic analysis of the role of two conserved Asp residues located in transmembrane segments X and XI of rat VMAT type I reveals an important role of these two residues in catalysis. Replacement of Asp 431 with either Glu or Ser inhibits VMAT-mediated [3H]serotonin transport. The mutated proteins are unimpaired in ligand recognition as measured with the high affinity ligand [3H]reserpine or coupling to the proton electrochemical gradient as judged by its ability to accelerate [3H]reserpine binding. Therefore, the Asp residue is needed as such in this position and even a conservative replacement with Glu generates a protein that can catalyze only partial reactions but cannot complete the transport cycle. Replacement of Asp 404 with either Ser or Cys inhibits all VMAT-mediated reactions measured. However, replacement with Glu generated a protein that catalyzed [3H]serotonin transport with modified properties. Whereas the mutated protein binds [3H]reserpine to normal levels and the pH optimum of this reaction is only slightly affected, the optimum pH for transport activity shifted to the acid side and became very sharp; in addition the sensitivity to the inhibitor tetrabenazine increased significantly in this mutated protein. The results point to the need of a carboxyl moiety in position 404. A slight change in its relative location or in the environment around it has a significant effect on the pK of group(s) involved in steps after ligand recognition and coupling to the first H+.

Histidine-419 plays a role in energy coupling in the vesicular monoamine transporter from rat.

Vesicular monoamine transporters (VMAT) catalyze transport of serotonin, dopamine, epinephrine and norepinephrine into subcellular storage organelles in a variety of cells. Accumulation of the neurotransmitter depends on the proton electrochemical gradient across the organelle membrane and involves VMAT-mediated exchange of two lumenal protons with one cytoplasmic amine. It has been suggested in the past that His residues play a role in H+ movement or in its coupling to active transport in H(+)-symporters and antiporters. Indeed VMAT-mediated transport is inhibited by reagents specific for His residues. We have identified one His residue in VMAT1 from rat which is conserved in other vesicular neurotransmitter transporters. Mutagenesis of this His (H419) to either Arg or Cys completely inhibits [3H]serotonin and [3H]dopamine accumulation. Mutagenesis also inhibits other H(+)-dependent partial reactions of VMAT such as the acceleration of binding of the high affinity ligand reserpine, but does not inhibit the [3H]reserpine binding which is not dependent on H+ translocation. It is concluded that His-419 plays a role in energy coupling in r-VMAT1.