D. Bunnachak et al., CA2-ACID, AND LDH RELEASE DURING PROXIMAL TUBULE HYPOXIA - EFFECTS OFMEPACRINE AND DIBUCAINE( UPTAKE, FATTY), The American journal of physiology, 266(2), 1994, pp. 60000196-60000201
In freshly isolated hypoxic rat proximal tubules, Ca2+ uptake rate inc
reases promptly, within 1 min, and remains significantly elevated thro
ughout a 20-min period of hypoxia. Lactate dehydrogenase (LDH) release
, a sign of membrane injury, increases only after 5 min of hypoxia and
thereafter rises progressively. The potential effect of increased Ca2
+ uptake rate to activate phospholipases, which would then initiate me
mbrane injury, was evaluated by treating hypoxic tubules with three di
ssimilar phospholipase inhibitors, i.e., mepacrine, dibucaine, or p-br
omophenacyl bromide (PBPB). LDH release averaged 11.9 and 13.8% after
10 and 20 min of normoxia, respectively. With 10 or 20 min of hypoxia
LDH release increased to 46.0 and 65.2%, respectively (P < 0.01), and
Ca2+ uptake rate increased from 2.56 in normoxia to 4.71 nmol mg(-1) m
in(-1) at 10 min of hypoxia (P < 0.01) and from 2.82 in normoxia to 3.
76 nmol/mg at 20 min of hypoxia (P < 0.05). In a separate series of tu
bules, after 10 min of hypoxia LDH release was reduced by pretreatment
with 50 mu M mepacrine (66.1 to 47.3%, P < 0.01) or 50 mu M dibucaine
(53.1 to 38.5%, P < 0.02). The increase in Ca2+ uptake rate also was
significantly reduced. After 20 min of hypoxia neither mepacrine nor d
ibucaine reduced Ca2+ uptake rate; LDH release was modestly reduced by
dibucaine but not mepacrine. Higher doses of mepacrine (500 mu M) and
dibucaine (250 mu M) also reduced cell injury at 10 min of hypoxia as
assessed by LDH release. With 10 min of hypoxia, 50 mu M mepacrine di
d not reduce free fatty acids (FFA); 500 mu M mepacrine reduced levels
of two of the five species of fatty acids determined. Dibucaine at 50
mu M reduced the levels of three of the five fatty acids, but higher
concentrations (250 mu M) failed to lower FFA. No protective effects o
f PBPB (100 mu M) were observed. Thus mepacrine and dibucaine, but not
PBPB, reduce the early cellular damage, as assessed by LDH release, t
hat occurs with hypoxia and attenuate the hypoxia-associated increases
in Ca2+ uptake rate. This cellular protection does not correlate cons
istently with the ability of these agents to inhibit fatty acid releas
e during hypoxia. The protective effects of mepacrine and dibucaine ar
e not demonstrable by 20 min of hypoxia, thus suggesting that continue
d phospholipase activity or other noxious events such as cell swelling
, O-2-free radicals, and/or proteases may predominate at this time.