thymosin and Necrosis

Following stroke or traumatic damage, neuronal death via both necrosis and apoptosis causes loss of functions, including memory, sensory perception, and motor skills. As necrosis has the nature to expand, while apoptosis stops the cell death cascade in the brain, necrosis is considered to be a promising target for rapid treatment for stroke. We identified the nuclear protein, prothymosin alpha (ProTalpha) from the conditioned medium of serum-free culture of cortical neurons as a key protein-inhibiting necrosis. In the culture of cortical neurons in the serum-free condition without any supplements, ProTalpha inhibited the necrosis, but caused apoptosis. In the ischemic brain or retina, ProTalpha showed a potent inhibition of both necrosis and apoptosis. By use of anti-brain-derived neurotrophic factor or anti-erythropoietin IgG, we found that ProTalpha inhibits necrosis, but causes apoptosis, which is in turn inhibited by ProTalpha-induced neurotrophins under the condition of ischemia. From the experiment using anti-ProTalpha IgG or antisense oligonucleotide for ProTalpha, it was revealed that ProTalpha has a pathophysiological role in protecting neurons in stroke.

Topics: Apoptosis; Brain; Brain-Derived Neurotrophic Factor; Cell Death; Cerebral Cortex; Culture Media, Conditioned; Erythropoietin; Immunoproteins; Ischemia; Necrosis; Nerve Growth Factors; Neurons; Protein Precursors; Retina; Stroke; Thymosin

Exposure of tissues to sulfur mustard (SM) results in the formation of protein and nucleotide adducts that disrupt cellular metabolism and cause cell death. Subsequent pathologies involve a significant proinflammatory response, disrupted healing, and long-term defects in tissue architecture. Following ocular exposure, acute corneal sequelae include epithelial erosions, necrosis, and corneal inflammation. Longer term, a progressive injury becomes distributed throughout the anterior chamber, which ultimately causes a profound remodeling of corneal tissues. In many cases, debilitating and vision-threatening injuries reoccur months to years after the initial exposure. Preliminary data in humans suffering from chronic epithelial lesions suggest that thymosin beta4 (Tbeta4) may be a viable candidate to mitigate acute or long-term ocular SM injury. To evaluate therapeutic candidates, we have developed a rabbit ocular exposure model system. In this paper, we report molecular, histological, ultrastructural, and clinical consequences of rabbit ocular SM injury, which can be used to assess Tbeta4 efficacy, including timepoints at which Tbeta4 will be assessed for therapeutic utility.

Topics: Animals; Cornea; Eye; Eye Injuries; Humans; Male; Mice; Mustard Gas; Necrosis; Physiological Phenomena; Rabbits; Thymosin; Wound Healing

Following stroke or traumatic damage, neuronal death via both necrosis and apoptosis causes loss of functions including memory, sensory perception and motor skills. Since necrosis has the nature to expand, while apoptosis stops the cell death cascade in the brain, necrosis is considered to be a promising target for rapid treatment for stroke. Pure neuronal necrosis occurs when cortical neurons are cultured under serum-free and low-density conditions. Prothymosin alpha (ProTalpha) isolated from conditioned medium after serum-free culture was found to prevent necrosis by recovering the energy crisis due to endocytosed glucose transporters. At a later time point under the same starvation conditions, ProTalpha causes apoptosis, which in turn seems to inhibit the rapidly occurring necrosis by cleaving poly (ADP-ribose) polymerase, a major machinery involved in ATP consumption. Indeed, ProTalpha administered via systemic routes markedly inhibits the histological and functional damage induced by cerebral and retinal ischemia. Although ProTalpha also causes a cell death mode switch from necrosis to apoptosis in vivo, the induced apoptosis was found to be completely inhibited by endogenously occurring brain-derived neurotrophic factor or erythropoietin. Since forced downregulation of ProTalpha deteriorates the ischemic damage, it is evident that ProTalpha plays in vivo neuroprotective roles after ischemic events. Analyses in terms of the therapeutic time window and potency suggest that ProTalpha could be the prototypic compound to develop the medicine useful for treatment of stroke in clinics.

Topics: Animals; Apoptosis; Brain Ischemia; Cell Death; Drug Delivery Systems; Glucose Transport Proteins, Facilitative; Humans; Ischemia; Necrosis; Neurons; Protein Precursors; Retinal Diseases; Thymosin

After stroke or traumatic damages, both necrotic and apoptotic neuronal death cause a loss of functions including memory, sensory perception, and motor skills. From the fact that necrosis has a nature to expand, while apoptosis to cease the cell death cascade in the brain, it is considered that the promising target for the rapid treatment for stroke is the necrosis. In this study, I introduce the discovery of prothymosin alpha (ProTalpha), which inhibits neuronal necrosis, and propose its potentiality of clinical use for stroke. First of all, it should be noted that ProTalpha inhibits the neuronal necrosis induced by serum-free starvation or ischemia-reperfusion stress, which causes a rapid internalization of GLUT1/4, leading a decrease in glucose uptake and cellular ATP levels. Underlying mechanisms are determined to be through an activation of Gi/o, phospholipase C and PKCbetaII. ProTalpha also causes apoptosis later through a similar mechanism. However, we found that ProTalpha-induced apoptosis is completely inhibited by the concomitant treatment with neurotrophins, which are up-regulated by ischemic stress in the brain. Of most importance is the finding that the systemic injection of ProTalpha completely inhibits the brain damages, motor dysfunction and learning memory defect induced by cerebral ischemia-reperfusion stress. As ProTalpha almost entirely prevents the focal ischemia-induced motor dysfunction 4 h after the start of ischemia, this protein seems to have a promising potentiality for clinical use.

Topics: Adenosine Triphosphate; Animals; Cell Death; Drug Delivery Systems; Glucose; Glucose Transporter Type 1; Glucose Transporter Type 4; Humans; Necrosis; Neurons; Protein Precursors; Stroke; Thymosin

To study the effects of exogenous thymosinβ4 (Tβ4) treatment in acetaminophen (APAP)-induced hepatotoxicity.. Liver injury was induced in mice by a single intraperitoneal injection of APAP (500 mg/kg). Exogenous Tβ4 was intraperitoneally administrated at 0 h, 2 h and 4 h after APAP injection. Chloroquine (CQ) (60 mg/kg) was intraperitoneally injected 2 h before APAP administration to inhibit autophagy. Six hours after APAP injection liver injury was evaluated by histological examinations, biochemical measurements and enzyme linked immunosorbent assay (ELISAs). Western blots were performed to detect proteins expression.. Serum alanine aminotransferase (ALT) and aspartate aminotransferase (AST) activities were significantly increased 6 h after APAP administration, but were significantly reduced by co-administration of Tβ4. Histological examinations demonstrated that Tβ4 reduced necrosis and inflammation induced by APAP. Immunofluorescence showed that Tβ4 suppressed APAP-induced translocation of high mobility group box-1 protein (HMGB1) from the nucleus to cytosol and intercellular space. Hepatic glutathione (GSH) depletion, malondialdehyde (MDA) formation and decreased superoxide dismutase (SOD) activities induced by APAP were all attenuated by Tβ4. APAP-induced increases in hepatic nuclear factor-κB (NF-κB) p65 protein expression and inflammatory cytokines production including interleukin-1β (IL-1β) and tumor necrosis factor-α (TNF-α) were reduced by Tβ4 treatment. Increased LC3 and p62 proteins in the liver tissues of APAP-treated mice were decreased by Tβ4 treatment, which indicated the enhancement of autophagy flux by Tβ4. Furthermore, inhibiting autophagy by CQ abrogated the protective effects of Tβ4 against APAP hepatotoxicity.. Exogenous Tβ4 treatment exerts protective effects against APAP-induced hepatotoxicity in mice. The underneath molecular mechanisms may involve autophagy enhancement and inhibition of oxidative stress by Tβ4.

Topics: Acetaminophen; Alanine Transaminase; Animals; Antioxidants; Aspartate Aminotransferases; Autophagy; Chemical and Drug Induced Liver Injury; Disease Models, Animal; HMGB1 Protein; Humans; Interleukin-1beta; Liver; Male; Mice; Mice, Inbred BALB C; Necrosis; Thymosin; Tumor Necrosis Factor-alpha

The nuclear protein prothymosin-α (ProTα), which lacks a signal peptide sequence, is released from neurons and astrocytes on ischemic stress and exerts a unique form of neuroprotection through an anti-necrotic mechanism. Ischemic stress-induced ProTα release is initiated by a nuclear release, followed by extracellular release in a non-vesicular manner, in C6 glioma cells. These processes are caused by ATP loss and elevated Ca²(+), respectively. S100A13, a Ca²(+)-binding protein, was identified to be a major protein co-released with ProTα in an immunoprecipitation assay. The Ca²(+)-dependent interaction between ProTα and S100A13 was found to require the C-terminal peptide sequences of both proteins. In C6 glioma cells expressing a Δ88-98 mutant of S100A13, serum deprivation caused the release of S100A13 mutant, but not of ProTα. When cells were administered apoptogenic compounds, ProTα was cleaved by caspase-3 to generate a C-terminal peptide-deficient fragment, which lacks the nuclear localization signal (NLS). However, there was no extracellular release of ProTα. All these results suggest that necrosis-inducing stress induces an extacellular release of ProTα in a non-vesicular manner, whereas apoptosis-inducing stress does not, owing to the loss of its interaction with S100A13, a cargo molecule for extracellular release.

Topics: Adenosine Triphosphate; Animals; Apoptosis; Astrocytes; Caspase 3; Cell Line, Tumor; Cell Nucleus; Cells, Cultured; Cytosol; Glioma; Immunoblotting; Ischemia; Necrosis; Neurons; Nuclear Localization Signals; Nuclear Proteins; Polymerase Chain Reaction; Protein Precursors; Rats; S100 Proteins; Signal Transduction; Stress, Physiological; Thymosin

Prothymosin-alpha (ProTalpha) causes a switch in cell death mode from necrosis to neurotrophin-reversible apoptosis in primary cultured cortical neurons. In the present study, post-ischemic administration (3 or 24 h, intravenously) of recombinant mouse ProTalpha without neurotrophins completely prevented ischemia-induced retinal damage accompanying necrosis and apoptosis, as well as dysfunction assessed by electroretinogram. Treatments with anti-erythropoietin (EPO) or brain-derived neurotrophic factor (BDNF) immunoglobulin G (IgG) reversed ProTalpha-induced inhibition of apoptosis. ProTalpha upregulated retinal EPO and BDNF levels in the presence of ischemia. Moreover, intravitreous administration of anti-ProTalpha IgG or an antisense oligodeoxynucleotide for ProTalpha accelerated ischemia-induced retinal damage. We also observed that ischemia treatment caused a depletion of ProTalpha from retinal cells. Altogether, these results suggest that the systemic administration of ProTalpha switches ischemia-induced necrosis to apoptosis, which in turn is inhibited by neurotrophic factors upregulated by ProTalpha and ischemia. ProTalpha released upon ischemic stress was found to have a defensive role in retinal ischemia.

Topics: Animals; Antibodies; Apoptosis; Brain-Derived Neurotrophic Factor; Erythropoietin; Ischemia; Male; Mice; Necrosis; Protein Precursors; Reperfusion Injury; Retina; Retinal Vessels; Thymosin

We initially identified a nuclear protein, prothymosin-alpha1 (ProTalpha), as a key protein inhibiting necrosis by subjecting conditioned media from serum-free cultures of cortical neurons to a few chromatography steps. ProTalpha inhibited necrosis of cultured neurons by preventing rapid loss of cellular adenosine triphosphate levels by reversing the decreased membrane localization of glucose transporters but caused apoptosis through up-regulation of proapoptotic Bcl(2)-family proteins. The apoptosis caused by ProTalpha was further inhibited by growth factors, including brain-derived neurotrophic factor. The ProTalpha-induced cell death mode switch from necrosis to apoptosis was also reproduced in experimental ischemia-reperfusion culture experiments, although the apoptosis level was markedly reduced, possibly because of the presence of growth factors in the reperfused serum. Knock down of PKCbeta(II) expression prevented this cell death mode switch. Collectively, these results suggest that ProTalpha is an extracellular signal protein that acts as a cell death mode switch and could be a promising candidate for preventing brain strokes with the help of known apoptosis inhibitors.

Topics: Amino Acid Sequence; Animals; Apoptosis; Cells, Cultured; Cerebral Cortex; Culture Media, Conditioned; Molecular Sequence Data; Necrosis; Neurons; Protein Precursors; Rats; Thymosin

Topics: Animals; Apoptosis; Brain; Cerebrovascular Disorders; Disease Models, Animal; Dose-Response Relationship, Drug; Necrosis; Protein Precursors; Rats; Stroke; Thymosin

Zinc exhibits inhibitory effects on apoptosis, and a deficiency in this metal generally causes this type of cell death to occur. In the present study, we found that exposure to zinc results in necrosis of prostate carcinoma cells. When zinc acetate was added to LNCaP or PC-3 cells in monolayer culture, they began to detach from the culture dishes, and viability was lost after 4-8 h. Most of the cell death was found to be due to necrosis as determined by double staining with fluorescein-isothiocyanate-labeled annexin V and ethidium bromide, and by detection of hypodiploid cells. Associated with the induction of necrosis was an increase in low molecular-mass proteins, identified by HPLC analysis to be thymosin beta10, parathymosin and GAGE in LNCaP cells, and thymosin beta4, parathymosin and metallothionein in PC-3. The time course of the increase of thymosin beta10 in LNCaP cells and thymosin beta4 in PC-3 cells was consistent with that of appearance of cell detachment and dead cells. These results indicate that zinc can induce necrosis and suggest that production of proteins including beta-thymosins is involved in induction of processes leading to cell detachment.

Topics: Adenocarcinoma; Annexin A5; Apoptosis; Cell Adhesion; Cell Division; Cell Survival; Copper; DNA, Neoplasm; Humans; Male; Metallothionein; Necrosis; Neoplasm Proteins; Prostatic Neoplasms; Thymosin; Tumor Cells, Cultured; Zinc

We have shown the in vivo usefulness of a novel chimera tumor necrosis factor (TNF), called rTNF-STH, which was constituted with human thymosin beta 4 and recombinant human TNF-SAM1. Tumor necrosis was induced by intravenous injection of a smaller amount of rTNF-STH (1 x 10(3) U/mouse, 0.67 microgram/mouse) than rTNF-alpha or rTNF-S (1 x 10(4) U/mouse, 2.5-5 micrograms/mouse). Significant antitumor effects of rTNF-STH to Meth A fibrosarcoma, B16 melanoma, MH134 hepatoma, or Lewis lung carcinoma (3LL) were observed by systemic injection of rTNF-STH at the maximum tolerable dose of 1 x 10(4) U/mouse (6.7 micrograms/mouse); this dose did not cause regression of tumors by conventional rTNF-alpha. rTNF-STH showed a significant prolongation of its half-life in serum. The average calculated half-life of the chimera protein is about 110 min, which is 15 times longer than that of original TNF-SAM1 (7.5 min). On the basis of this prolongation of half-life of rTNF-STH and its efficient hemorrhagic necrotic activity, the antitumor effect of rTNF-STH--as compared with that of the known TNF species--is discussed. Findings indicate that use of the chimera protein to alter the N-terminal region of TNF may be a promising approach to obtain molecules that more favorably attack tumors and other diseases than conventional rTNFs.

Topics: Animals; Fibrosarcoma; Half-Life; Liver Neoplasms, Experimental; Lung Neoplasms; Melanoma, Experimental; Mice; Mice, Inbred BALB C; Mice, Inbred C3H; Mice, Inbred C57BL; Necrosis; Neoplasm Transplantation; Neoplasms, Experimental; Recombinant Fusion Proteins; Recombinant Proteins; Thymosin; Tumor Necrosis Factor-alpha