Erythrocyte survival is promoted by plasma and suppressed by a Bak-derived BH3 peptide that interacts with membrane-associated Bcl-XL

Walsh, Melanie; Lutz, Robert J.; Cotter, Thomas G.; O’Connor, Rosemary

doi:10.1182/blood.v99.9.3439

Cited by 31 publications

(33 citation statements)

References 49 publications

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“…In partial agreement with observations by Walsh et al [21], who studied whole red cell population under the same culture conditions, we found that a lower percentage of young, middle aged and old cells could be recovered from cultures in plasma-free medium than from those with plasma. Furthermore, neocytes showed the lowest survival rate at each time point in both culture mediums ( p <0,01) (Fig.…”

Section: Resultssupporting

confidence: 81%

Survival and Senescence of Human Young Red Cellsin Vitro

Risso

Ciana

Achilli

et al. 2014

Cell Physiol Biochem

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Background: A number of experimental investigations in vivo suggest that in humans a decrease of circulating erythrocyte number ensues whenever erythropoietin (EPO) plasma level decreases. Since the process seems to selectively eliminate young red cells (neocytes), it has been named neocytolysis. The experimental models in vivo have revealed and documented multiple forms of neocytolysis but have not fully elucidated the specificity of the target red cells and the relation with EPO level changes. In an attempt to better characterize the neocytolytic process, we have undertaken an in vitro investigation on age-ranked human red cells. Methods: By centrifugation on Percoll density gradient we separated the red cells population into three subsets, neocytes, middle-aged and old. Then we comparatively investigated the kinetics of survival of the subsets cultured under different conditions: with medium alone, with 10% autologous plasma, with EPO, alone or in combination with autologous monocytes. Results: Neocytes showed a viability and a survival rate lower than the other red cells when cultured in medium or with 10% plasma. EPO at physiological doses increased their survival rate, but not that of the other subsets. This effect was enhanced by co-culture with monocytes. Conclusion: Likely neocytes are more sensitive than the other RBCs subsets to presence or absence of survival signals, such as EPO or plasma or monocytes derived factors. These observations could provide an insight into the link between the decrease in EPO plasma level and the reduction of circulating red cells mass and account for the specificity of neocytes clearance.

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Section: Resultssupporting

confidence: 81%

Survival and Senescence of Human Young Red Cellsin Vitro

Risso

Ciana

Achilli

et al. 2014

Cell Physiol Biochem

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“…To determine the effect of AnkP peptide on the growth and development of P. falciparum, we utilized a recent technique where peptides were delivered into intact RBCs by fusion with the Antennapedia homeoprotein internalization domain (22). Human erythrocytes infected with stage-specific parasites were incubated with 100 -250 M of the fused peptide (AntAnkP).…”

Section: Discussionmentioning

confidence: 99%

“…Peptides were synthesized by fusing with the 16 amino acid internalization sequence of Antennapedia (Ant) homeoprotein, which permits the uptake of peptides into cells via facilitated diffusion (21,22). Human erythrocytes infected with stage-specific P. falciparum were cultured in the presence of Ant-AnkP peptide, the Ant peptide alone, AnkP peptide alone, or a mutant form of the Ant-AnkP peptide where the AnkP portion was scrambled to eliminate the signature sequence of the cleavage site ( Table I).…”

Section: Falcipain-2 Cleaves Erythrocytementioning

confidence: 99%

Ankyrin Peptide Blocks Falcipain-2-mediated Malaria Parasite Release from Red Blood Cells

Dhawan

Dua

Chishti

et al. 2003

Journal of Biological Chemistry

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Falcipain-2 (FP-2) is a dual-function protease that cleaves hemoglobin at the early trophozoite stage and erythrocyte membrane ankyrin and protein 4.1 at the late stages of parasite development. FP-2-mediated cleavage of ankyrin and protein 4.1 is postulated to cause membrane instability facilitating parasite release in vivo. To test this hypothesis, here we have determined the precise peptide sequence at the hydrolysis site of ankyrin to develop specific inhibitor(s) of FP-2. Mass spectrometric analysis of the hydrolysis products showed that FP-2-mediated cleavage of ankyrin occurred immediately after arginine 1,210. A 10-mer peptide (ankyrin peptide, AnkP) containing the cleavage site completely inhibited the FP-2 enzyme activity in vitro and abolished all of the known functions of FP-2. To determine the effect of this peptide on the growth and development of P. falciparum, the peptide was delivered into intact parasite-infected red blood cells (RBCs) via the Antennapedia homeoprotein internalization domain. Growth and maturation of trophozoites and schizonts was markedly inhibited in the presence of the fused AnkP peptide. <10% of new ring-stage parasites were detected compared with the control sample. Together, our results identify a specific peptide derived from the spectrin-binding domain of ankyrin that blocks late-stage malaria parasite development in RBCs. Confocal microscopy with FP-2-specific antibodies demonstrated the proximity of the enzyme in apposition with the RBC membrane, further corroborating the proposed function of FP-2 in the cleavage of RBC skeletal proteins.Plasmodium falciparum causes the most severe form of human malaria and is responsible for nearly all malaria-induced mortality. Clinical manifestations of malaria are caused by the intraerythrocytic life cycle of P. falciparum. The parasite undergoes distinct morphologic changes during its 48-h life cycle inside human red blood cells (RBCs) 1 (1). After invasion into RBCs, the parasites mature from ring stage to trophozoites and then to schizonts. Mature segmented schizonts finally rupture the host erythrocytes releasing merozoites, which rapidly invade other erythrocytes to reinitiate the cycle. The mechanism of merozoite release from host RBCs is largely unknown. The cluster of merozoites inside a red blood cell is enclosed within two membranes: an inner parasitophorous vacuole membrane (PVM) and an outer RBC membrane. The rupture of these two membranes precedes the release of merozoites for subsequent round of RBC invasion. Several studies have shown that the merozoite release is susceptible to protease inhibitors. In the presence of such inhibitors, merozoites mature normally but are unable to escape from RBCs (2-4). Furthermore, a number of plasmodial proteases have been isolated and are shown to have activities against known RBC membrane skeletal proteins (5), although a functional role of these proteases in the rupture of the RBC membrane during merozoite escape has not been established.The issue of malaria parasite release fro...

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“…Altogether, these results suggest that the mitochondrial pathway to caspase activation is tightly regulated along the erythroid pathway of differentiation, a regulation that involves Bcl-X L and probably other Bcl-2-related proteins at the mitochondrion level (Aerbajinai et al, 2003). Surprisingly enough, a membrane-associated Bcl-X L was reported also to protect mature erythrocytes, which lack mitochondria, from death (Walsh et al, 2002).…”

Section: Mitochondria Caspases and Hematopoietic Cell Differentiationmentioning

confidence: 92%