Cryopreservation of buffy-coat-derived platelet concentrates in dimethyl sulfoxide and platelet additive solution

Platelets prepared in plasma can be frozen in 6% dimethyl sulfoxide (Me₂SO) and stored for extended periods at −80 °C. The aim of this study was to reduce the plasma present in the cryopreserved product, by substituting plasma with platelet additive solution (PAS; SSP+), whilst maintaining in vitro platelet quality. Buffy coat-derived pooled leukoreduced platelet concentrates were frozen in a mixture of SSP+, plasma and 6% Me₂SO. The platelets were concentrated, to avoid post-thaw washing, and frozen at −80 °C. The cryopreserved platelet units (n = 9) were rapidly thawed at 37 °C, reconstituted in 50% SSP+/plasma and stored at 22 °C. Platelet recovery and quality were examined 1 and 24 h post-thaw and compared to the pre-freeze samples. Upon thawing, platelet recovery ranged from 60% to 80%. However, there were differences between frozen and liquid-stored platelets, including a reduction in aggregation in response to ADP and collagen; increased CD62P expression; decreased viability; increased apoptosis and some loss of mitochondrial membrane integrity. Some recovery of these parameters was detected at 24 h post-thaw, indicating an extended shelf-life may be possible. The data suggests that freezing platelets in 6% Me₂SO and additive solution produces acceptable in vitro platelet quality.     

Taking organelles apart, putting them back together and creating new ones: lessons from the endoplasmic reticulum

The endoplasmic reticulum (ER) is a highly dynamic organelle. It is composed of four subcompartments including nuclear envelope (NE), rough ER (rER), smooth ER (sER) and transitional ER (tER). The subcompartments are interconnected, can fragment and dissociate and are able to reassemble again. They coordinate with cell function by way of protein regulators in the surrounding cytosol. The activity of the many associated molecular machines of the ER as well as the fluid nature of the limiting membrane of the ER contribute extensively to the dynamics of the ER. This review examines the properties of the ER that permit its isolation and purification and the physiological conditions that permit reconstitution both in vitro and in vivo in normal and in disease conditions.     

Evidence of intra-segmental homologous recombination in influenza A virus

The evolution of influenza viruses is remarkably dynamic. Influenza viruses evolve rapidly in sequence and undergo frequent reassortment of different gene segments. Homologous recombination, although commonly seen as an important component of dynamic genome evolution in many other organisms, is believed to be rare in influenza. In this study, 256 gene segments from 32 influenza A genomes were examined for homologous recombination, three recombinant H1N1 strains were detected and they most likely resulted from one recombination event between two closely rated parental sequences. These findings suggest that homologous recombination in influenza viruses tends to take place between strains sharing high sequence similarity. The three recombinant strains were isolated at different time periods and they form a clade, indicating that recombinant strains could circulate. In addition, the simulation results showed that many recombinant sequences might not be detectable by currently existing recombinant detection programs when the parental sequences are of high sequence similarity. Finally, possible ways were discussed to improve the accuracy of the detection for recombinant sequences in influenza.     

Mitochondrial calcium handling during ischemia-induced cell death in neurons

Mitochondria sense and shape cytosolic Ca²⁺ signals by taking up and subsequently releasing Ca²⁺ ions during physiological and pathological Ca²⁺ elevations. Sustained elevations in the mitochondrial matrix Ca²⁺ concentration are increasingly recognized as a defining feature of the intracellular cascade of lethal events that occur in neurons during cerebral ischemia. Here, we review the recently identified transport proteins that mediate the fluxes of Ca²⁺ across mitochondria and discuss the implication of the permeability transition pore in decoding the abnormally sustained mitochondrial Ca²⁺ elevations that occur during cerebral ischemia.     

Monoamine oxidases (MAO) in the pathogenesis of heart failure and ischemia/reperfusion injury

Recent evidence highlights monoamine oxidases (MAO) as another prominent source of oxidative stress. MAO are a class of enzymes located in the outer mitochondrial membrane, deputed to the oxidative breakdown of key neurotransmitters such as norepinephrine, epinephrine and dopamine, and in the process generate H₂O₂. All these monoamines are endowed with potent modulatory effects on myocardial function. Thus, when the heart is subjected to chronic neuro-hormonal and/or peripheral hemodynamic stress, the abundance of circulating/tissue monoamines can make MAO-derived H₂O₂ production particularly prominent. This is the case of acute cardiac damage due to ischemia/reperfusion injury or, on a more chronic stand, of the transition from compensated hypertrophy to overt ventricular dilation/pump failure. Here, we will first briefly discuss mitochondrial status and contribution to acute and chronic cardiac disorders. We will illustrate possible mechanisms by which MAO activity affects cardiac biology and function, along with a discussion as to their role as a prominent source of reactive oxygen species. Finally, we will speculate on why MAO inhibition might have a therapeutic value for treating cardiac affections of ischemic and non-ischemic origin. This article is part of a Special Issue entitled: Mitochondria and Cardioprotection.     

High expression of GLT-1 in hippocampal CA3 and dentate gyrus subfields contributes to their inherent resistance to ischemia in rats

It is well known that neurons in the CA3 and dentate gyrus (DG) subfields of the hippocampus are resistant to short period of ischemia which is usually lethal to pyramidal neurons in hippocampal CA1 subfield. The present study was undertaken to clarify whether the inherent higher resistance of neurons in CA3 and DG to ischemia is associated with glial glutamate transporter-1 (GLT-1) in rats. Western blot analysis and immunohistochemistry assay showed that the basal expressions of GLT-1 in both CA3 and DG were much higher than that in CA1 subfield. Mild global brain ischemia for 8 min induced delayed death of almost all CA1 pyramidal neurons and marked GLT-1 down-regulation in the CA1 subfield, but it was not lethal to the neurons in either CA3 or DG and induced GLT-1 up-regulation and astrocyte activation showed normal soma and aplenty slender processes in the both areas. When the global brain ischemia was prolonged to 25 min, neuronal death was clearly observed in CA3 and DG accompanied with down-regulation of GLT-1 expression and abnormal astrocytes represented with hypertrophic somas, but shortened processes. After down-regulating of GLT-1 expression and function by its antisense oligodeoxynucleotides or inhibiting GLT-1 function by dihydrokainate, an inhibitor of GLT-1, the mild global brain ischemia for 8 min, which usually was not lethal to CA3 and DG neurons, induced the neuronal death in CA3 and DG subfields. Taken together, the higher expression of GLT-1 in the CA3 and DG contributes to their inherent resistance to ischemia.     

Protective effects of L-pGlu-(2-propyl)-L-His-L-ProNH2, a newer thyrotropin releasing hormone analog in in vitro and in vivo models of cerebral ischemia

In the present study, the newly synthesized TRH analog (l-pGlu-(2-propyl)-l-His-l-ProNH₂; NP-647) was evaluated for its effects in in vitro (oxygen glucose deprivation (OGD)-, glutamate- and H₂O₂-induced injury in PC-12 cells) and in vivo (transient global ischemia) models of cerebral ischemic injury. PC-12 cells were subjected to oxygen and glucose deprivation for 6 h. Exposure of NP-647 was given before and during OGD. In glutamate and H₂O₂ induced injury, exposure of NP-647 was given 1, 6 and 24 h prior to exposure of glutamate and H₂O₂ exposure. NP-647, per se found to be non-toxic in 1-100 μM concentrations. NP-647 showed protection against OGD at the 1 and 10 μM. The concentration-dependent protection was observed in H₂O₂- and glutamate-induced cellular injury. In in vivo studies, NP-647 treatment showed protection of hippocampal (CA1) neuronal damage in transient global ischemia in mice and subsequent improvement in memory retention was observed using passive avoidance retention test. Moreover, administration of NP-647 resulted in decrease in inflammatory cytokines TNF-α and IL-6 as well as lipid peroxidation. These results suggest potential of NP-647 in the treatment of cerebral ischemia and its neuroprotective effect may be attributed to reduction of excitotoxicity, oxidative stress and inflammation.     

心脏的再生性研究进展

心力衰竭(心衰)是由多种心血管疾病引起的心功能不全,最终出现心肌局部坏死和不可逆转的纤维化。传统的药物治疗、介入和外科治疗方案都存在着一定的局限性。随着转化医学的发展,心脏再生和修复无疑是解决以上临床问题的最佳方案,基础研究的成果正在为临床实践提供理论基础。文章从心脏再生性修复策略、心肌细胞来源、重编程和模式动物等几个方面的进展概括了整个心脏再生领域的发展。     

Expression of human equilibrative nucleoside transporter 1 in mouse neurons regulates adenosine levels in physiological and hypoxic-ischemic conditions

Activation of adenosine A(1) receptors inhibits excitatory synaptic transmission. Equilibrative nucleoside transporters (ENTs) regulate extracellular adenosine levels; however, the role of neuronal ENTs in adenosine influx and efflux during cerebral ischemia has not been determined. We used mice with neuronal expression of human ENT type 1 and wild type (Wt) littermates to compare responses to in vitro hypoxic or ischemic conditions. Extracellular recordings in the CA1 region of hippocampal slices from transgenic (Tg) mice revealed increased basal synaptic transmission, relative to Wt slices, and an absence of 8-cyclopentyl-1,3-dipropyl-xanthine mediated augmentation of excitatory neurotransmission. Adenosine (10-100 μM) had a reduced potency for inhibiting synaptic transmission in slices from Tg mice; inhibitory concentration 50% values were approximately 25 and 50 μM in Wt and Tg slices, respectively. Potency of the A(1) receptor agonist N(6) -cyclopentyladenosine (1 nM-1 μM) was unchanged. Transient hypoxia or oxygen-glucose deprivation produced greater inhibition of excitatory neurotransmission in slices from Wt than Tg, mice. The ENT1 inhibitor S-(4-nitrobenzyl)-6-thioinosine abolished these differences. Taken together, our data provide evidence that neuronal ENTs reduce hypoxia- and ischemia-induced increases in extracellular adenosine levels and suggest that inhibition of neuronal adenosine transporters may be a target for the treatment of cerebral ischemia.     

Impairment of ubiquitin-proteasome system by E334K cMyBPC modifies channel proteins, leading to electrophysiological dysfunction

Cardiac arrhythmogenesis is regulated by channel proteins whose protein levels are in turn regulated by the ubiquitin-proteasome system (UPS). We have previously reported on UPS impairment induced by E334K cardiac myosin-binding protein C (cMyBPC), which causes hypertrophic cardiomyopathy (HCM) accompanied by arrhythmia. We hypothesized that UPS impairment induced by E334K cMyBPC causes accumulation of cardiac channel proteins, leading to electrophysiological dysfunction. Wild-type or E334K cMyBPC was overexpressed in HL-1 cells and primary cultured neonatal rat cardiac myocytes. The expression of E334K cMyBPC suppressed cellular proteasome activities. The protein levels of K_v1.5, Na_v1.5, Hcn4, Ca_v3.2, Ca_v1.2, Serca, RyR2, and Ncx1 were significantly higher in cells expressing E334K cMyBPC than in wild type. They further increased in cells pretreated with MG132 and had longer protein decays. The channel proteins retained the correct localization. Cells expressing E334K cMyBPC exhibited higher Ca²⁺ transients and longer action potential durations (APDs), accompanied by afterdepolarizations and higher apoptosis. Those augments of APD and Ca²⁺ transients were recapitulated by a simulation model. Although a Ca²⁺ antagonist, azelnidipine, neither protected E334K cMyBPC from degradation nor affected E334K cMyBPC incorporation into the sarcomere, it normalized the APD and Ca²⁺ transients and partially reversed the levels of those proteins regulating apoptosis, thereby attenuating apoptosis. In conclusion, UPS impairment caused by E334K cMyBPC may modify the levels of channel proteins, leading to electrophysiological dysfunction. Therefore, UPS impairment due to a mutant cMyBPC may partly contribute to the observed clinical arrhythmias in HCM patients.