Erythrocyte Li&lt;sup&gt;+&lt;/sup&gt;&lt;sub&gt;i&lt;/sub&gt;-Na&lt;sup&gt;+&lt;/sup&gt;&lt;sub&gt;o&lt;/sub&gt; Countertransport in the Newborn

The kinetic parameters of Na(+)-Li+ exchange were studied in both neonatal and adult's red blood cells in order to evaluate if the asymmetry for Li+ fluxes (Na(+)-contralateral-dependent) is expressed in both types of cells. Maximum velocities (Vmax) and Km (half-activation constant) were measured for Li+ fluxes in both types of cells. In human neonatal red blood cells (nRBC), extracellular Na+-dependent Li+ efflux was shown to be a saturable function of external sodium concentration with high affinity (apparent Km: 2.1 mM) and low capacity (maximal velocity Vmax = 0.3 mmoles Li+ 1('''10 cells h(-1)). The Vmax and apparent Km for cellular Na(+)-dependent Li+ influx were higher (Km = 12.9 mM; Vmax = 1.07 mmoles Li+ 1(-1) cells h(-1)). The results provide evidence for intrinsic functional asymmetry in this transport system, as the transporter is more prevalent and stable in the inward-facing conformation. These kinetic observations may be explained in terms of the simple carrier transport model. Similar findings were found for this system in human adult's red cells. These results point to the asymmetry pattern (related to Na+ activation of Li+ flux) as developed in red cells from late prenatal stages of hemopoiesis.

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Expression and Activity of the Ca2+-ATPase Enzyme in Human Neonatal Erythrocytes

Kocsis

Vásárhelyi

Héninger

et al. 2001

Neonatology

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The plasma membrane Ca²⁺-ATPase (PMCA) is one of the main regulators of Ca²⁺ homeostasis. We studied the perinatal alteration of the abundance and the activity of PMCA molecules in human erythrocytes in pre-term and full-term neonates and children at the age of 1–4 years. The lower abundance of the 4b isoform was associated with lower enzyme activity in full-term neonates compared to children. Although the number of PMCA molecules was higher in pre-term neonates, their total PMCA activities were identical to those of full-term neonates. Our findings suggest that the abundance of PMCA molecules changes during the perinatal development. The same activity at higher enzyme molecule numbers might indicate a potential immaturity of the enzyme in the pre-term infant.

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Erythrocyte Li<sup>+</sup><sub>i</sub>-Na<sup>+</sup><sub>o</sub> Countertransport in the Newborn

Cited by 3 publications

References 19 publications

Human red cells from prenatal hemopoiesis. Sodium/lithium exchange symmetry

Human red cells from prenatal hemopoiesis. Sodium/lithium exchange symmetry

HUMAN RED CELLS FROM PRE (HEPATO SPLENIC-LATE FETAL) AND POSTNATAL (BONE MARROW-ADULT') STAGES OF HAEMOPOIESIS: NA⁺/LI⁺EXCHANGE KINETIC

Expression and Activity of the Ca<sup>2+</sup>-ATPase Enzyme in Human Neonatal Erythrocytes

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Erythrocyte Li<sup>+</sup><sub>i</sub>-Na<sup>+</sup><sub>o</sub> Countertransport in the Newborn

Cited by 3 publications

References 19 publications

Human red cells from prenatal hemopoiesis. Sodium/lithium exchange symmetry

Human red cells from prenatal hemopoiesis. Sodium/lithium exchange symmetry

HUMAN RED CELLS FROM PRE (HEPATO SPLENIC-LATE FETAL) AND POSTNATAL (BONE MARROW-ADULT') STAGES OF HAEMOPOIESIS: NA+/LI+EXCHANGE KINETIC

Expression and Activity of the Ca<sup>2+</sup>-ATPase Enzyme in Human Neonatal Erythrocytes

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Product

Resources

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HUMAN RED CELLS FROM PRE (HEPATO SPLENIC-LATE FETAL) AND POSTNATAL (BONE MARROW-ADULT') STAGES OF HAEMOPOIESIS: NA⁺/LI⁺EXCHANGE KINETIC