Some quantitative aspects of myoplasmic ATPMg and total internal ATP and ArP levels in resting barnacle muscle fibres

Characterization of Arginine Kinase in the Barnacle Amphibalanus Amphitrite and Its Role in the Larval Settlement

Energy metabolism is a key process in larval settlement of barnacles, but the underlying molecular mechanisms remain ambiguous. Arginine kinase (AK) mainly participates in energy metabolism in invertebrates. So far, its roles in barnacles have not been studied. In the present study, we raised an antibody against AK from Amphibalanus amphitrite Darwin to characterize the roles of AK in the larval settlement process. Among the developmental stages, AK was highly expressed during the cypris stage. Along with the aging process in cyprids, the level of AK decreased. The immunostaining results showed that AK was localized to muscular tissues in cyprids, including antennules, antennular muscles, and thoracic limbs. The larval settlement rate decreased and larval movement was inhibited in response to treatments with high concentrations of AK inhibitors (rutin and quercetin). These results demonstrated that AK was involved in the larval settlement of A. amphitrite through mediating energy supply in muscle tissues. Moreover, further analysis indicated that both the p38 MAPK and NO/cGMP pathways positively mediated the expression of AK in cyprids.

Characterization of N omega-phosphoarginine hydrolase from rat liver

N omega-Phosphoarginine hydrolase from rat liver hydrolyzed N omega-phosphoarginine into arginine and inorganic phosphate, whereas it did not release inorganic phosphate from 19 other phosphorylated compounds containing a N-P bond, an O-P bond or a C-P bond. In addition, it was not able to transfer the phosphoryl moiety from N omega-phosphoarginine to ADP. These results indicated that this enzyme was distinct from both phosphoamidase and arginine kinase. Its properties were as follows: thiol compounds were essential for its activity; it was stimulated by 1.5-2-fold in the presence of 0.001% Lubrol, Tween 20, poly(oxyethylene) 9-lauryl ether and Nonidet P-40, while 0.004% sodium lauryl sulfate inhibited the activity completely; concentrations of sodium molybdate and sodium vanadate necessary for 50% inhibition were 7 microM and 12 microM, respectively; some proteins stimulated the activity, while lysophosphatidic acid, lysophosphatidylinositol, and phosphatidic acid suppressed the activity even in the presence of poly(oxyethylene) 9-lauryl ether.

Some further observations on the stimulation by high external potassium of the sodium efflux in barnacle muscle fibers

A study has been made in single barnacle muscle fibers of the mechanism underlying the stimulatory response of the ouabain-insensitive Na efflux to high K0. Fibers poisoned with ouabain and preinjected with GTPNa2 show a biphasic stimulatory response to 100 mM K0 which is practically abolished by exposure of these fibers to verapamil. Prior or post-injection of cAMP-protein kinase type II regulatory subunits reduces the size of the response to 100 mM K0. Prior injection of cAMP-protein kinase catalytic subunits (CSU) attenuates the response to 100 mM K0 in fibers showing moderate sensitivity to CSU. In fibers showing extreme sensitivity to injected CSU, elevation of K0 partially reverses the sustained stimulatory response to CSU. Prior injection of Mg2+ leads to almost complete abolition of the response to 100 mM K0. External and internal application of F- reduces the response to 100 mM-K0. Injection of KF following decay of the response to high K0 results in a sustained stimulatory response. The drugs, chlorpromazine, trifluoperazine, imipramine and diphenylhydantoin are able to appreciably reduce the response to 100 mM K0. Taken together, these observations support the idea that the stimulatory response to high K0 is primarily due to activation by newly formed cAMP of cAMP-protein kinase, and that the transitory nature of the response and variable sensitivity of these fibers to high K0 is closely linked to the activity of a putative Mg2+-dependent protein phosphatase.