Isolation and molecular characterization of a cax gene from Capsella bursa-pastoris

A new cation exchangers (CAXs) gene was cloned and characterized from Capsella bursa-pastoris by rapid amplification of cDNA ends (RACE). The full-length cDNA sequence of cax from C. bursa-pastoris (designated as Cbcax51) was 1754 bp containing a 1398 bp open reading frame encoding a polypeptide of 466 amino-acid residues with a calculated molecular mass of 50.5 kDa and an isoelectric point of 5.69. The predicted CbCAX51 contained an IMP dehydrogenase/GMP reductase domain, two Na+/Ca2+ exchanger protein domains. Comparative and bioinformatics analyses revealed that CbCAX51 showed extensive homology with CAX from other plant species. The expression analysis by different treatments indicated that Cbcax51 could be activated by cold triggering and was related to the cold acclimation process, but its expression is regulated negatively by drought and not affected by ABA or salt.

Ca2+ transport and oxidative damage of mitochondria

1. Mitochondria from a wide range of sources have the ability to accumulate Ca2+ down their electrochemical gradient mediated by a uniport mechanism. 2. Ca2+ efflux occurs via two separate pathways: a Na+/Ca2+ exchanger that predominates in mitochondria from excitable tissues and a Na(+)-independent pathway that predominates in mitochondria from non-excitable tissues. 3. The kinetic characteristics of these calcium influx-efflux pathways appear to be incompatible with any role for mitochondria as cytosolic Ca2+ buffers, under resting normal physiological conditions. Instead, the biological role of this Ca(2+)-transporting system seems to be the regulation of matrix Ca2+ in a range that permits the regulation of three intramitochondrial Ca(2+)-dependent dehydrogenases which catalyze rate-limiting reactions of the Krebs cycle. 4. Under conditions in which a high cytosolic Ca2+ concentration is sustained, the matrix Ca2+ concentration may attain levels that lead to impairment of mitochondrial functions such as inhibition of oxidative phosphorylation and increase in inner membrane permeability. 5. Accumulation of Ca2+ by mitochondria under conditions of oxidative stress induces an increase in inner membrane permeability by a mechanism that appears to be mediated by protein polymerization due to thiol cross-linking