The essential cysteines in the CIPC motif of the thioredoxin-like Trypanosoma brucei MICOS subunit TbMic20 do not form an intramolecular disulfide bridge in vivo.

The mitochondrial protein import machinery of trypanosomatids is highly divergent from that of the well-studied models such as baker's yeast. A notable example is that the central catalyst of the mitochondrial intermembrane space import and assembly pathway (MIA), named Mia40, is missing in trypanosomatids. Mia40 works in a two-step process. First it recognizes by direct binding reduced MIA substrate proteins and then catalyzes their oxidative folding to produce intramolecular disulfide bridges. It was recently proposed that a thioredoxin-like subunit of the trypanosomal mitochondrial contact site and cristae organizing system (MICOS) called TbMic20 may be the Mia40 replacement. Our study performed on procyclic stage of the parasite revealed that each of the two cysteines in TbMic20's active site is essential for the stability of MIA substrate proteins although they do not form a disulfide bridge in vivo. The two cysteines of Mia40's active site form an intramolecular disulfide bridge at steady state, which is a prerequisite for its oxidative folding of MIA substrates. Thus, we conclude that TbMic20 is unlikely to represent a bona fide Mia40 replacement and plays a still unresolved role in the stability and/or import of MIA substrates in trypanosomatids. Despite this, the effect of TbMic20 depletion and mutation indicates that the trypanosomal MICOS complex still plays a vital role in the maturation and/or stability of proteins imported by the MIA pathway.

The Diverged Trypanosome MICOS Complex as a Hub for Mitochondrial Cristae Shaping and Protein Import.

The mitochondrial contact site and cristae organization system (MICOS) is a multiprotein complex responsible for cristae formation. Even though cristae are found in all mitochondria capable of oxidative phosphorylation, only Mic10 and Mic60 appear to be conserved throughout eukaryotes. The remaining 4 or 5 known MICOS subunits are specific to the supergroup Opisthokonta, which includes yeast and mammals that are the only organisms in which this complex has been analyzed experimentally. We have isolated the MICOS from Trypanosoma brucei, a member of the supergroup Excavata that is profoundly diverged from opisthokonts. We show that it is required for the maintenance of the unique discoidal cristae that typify excavates, such as euglenids and kinetoplastids, the latter of which include trypanosomes. The trypanosome MICOS consists of 9 subunits, most of which are essential for normal growth. Unlike in opisthokonts, it contains two distinct Mic10 orthologs and an unconventional putative Mic60 that lacks a mitofilin domain. Interestingly, one of the essential trypanosomatid-specific MICOS subunits called TbMic20 is a thioredoxin-like protein that appears to be involved in import of intermembrane space proteins, including respiratory chain complex assembly factors. This result points to trypanosome MICOS coordinating cristae shaping and population of its membrane with proteins involved in respiration, the latter via the catalytic activity of TbMic20. Thus, trypanosome MICOS allows us to define which of its features are conserved in all eukaryotes and decipher those that represent lineage-specific adaptations.

Relative roles of nitric oxide, prostanoids and angiotensin II in the regulation of canine glomerular hemodynamics. A micropuncture study.

Glomerular hemodynamics are controlled by a variety of physical, nervous and hormonal factors including the potent vasoconstrictors, angiotensin (ANG) II and endothelin-1 (ET-1), and the vasodilator prostanoids (prostaglandin = PG) and nitric oxide (NO). Since no micropuncture data on the canine kidney exist with respect to the relative roles of the endogenous vasoactive hormones/autacoids NO, PG and ANG II in modulating glomerular hemodynamics, in the present study using the micropuncture technique in anesthetized dogs on a normal salt intake, we investigated the relative effects of these hormones/autacoids by means of the L-arginine analog, N(omega)-nitro-L-arginine methyl ester hydrochloride (L-NAME), a competitive NO synthase (NOS) inhibitor, the cyclooxygenase inhibitor indomethacin (INDO), and the AT(1) receptor blocker EXP 3174. An intrarenal arterial (i.r.a.) bolus (within 5 min) of 2.5 mg of L-NAME led to a significant decrease in total renal blood flow (RBF) and single nephron glomerular blood flow (SNGBF) from 4.46 +/- 0.51 to 3.52 +/- 0.41 ml/min/g kidney weight and from 0.393 +/- 0.041 to 0.341 +/- 0.037 microl/min (p < 0.01), respectively, without a change in glomerular filtration rate (GFR). The increase in arteriolar resistance was more pronounced at the efferent (+31%) than at the afferent (+13%) arteriole, and K(f) decreased from 4.5 +/- 0.5 to 3.7 +/- 0.4 nl/min/mm Hg (p < 0.01). INDO (5 mg/kg i.v. bolus followed by 0.17 mg/kg/min i.v.) had no effect on glomerular hemodynamics. EXP 3174 (30 microg/kg/min i.r.a.) increased RBF and SNGBF from 4.35 +/- 0.45 to 4.99 +/- 0.50 ml/min/g kidney weight and from 0.403 +/- 0.028 to 0.478 +/- 0.039 microl/min (p < 0.01), respectively, without an effect on GFR. It reduced the efferent arteriolar resistance by 25% as compared to 13% at the afferent arteriolar level. EXP 3174 increased K(f) from 5.1 +/- 0.4 to 8.1 +/- 0.6 mm Hg (p < 0.01) in the presence of a decrease in effective filtration pressure from 13.2 +/- 1.7 to 8.3 +/- 1.0 mm Hg (p < 0.01). The glomerular hemodynamic effects of L-NAME were unaltered by pretreatment with INDO or EXP 3174, whereas its tubular effects were restored in the presence of EXP 3174. Thus, from these first micropuncture data in the anesthetized dog on a normal sodium intake we conclude that (1) acute intrarenal inhibition of NOS by L-NAME decreases RBF and SNGBF due to vasoconstriction of the afferent and, more pronounced, efferent arterioles. Since L-NAME simultaneously decreases K(f), GFR remains unaltered. (2) These renal hemodynamic effects of NOS inhibition were not mediated by prostanoids or intrarenal ANG II. Thus, the tonic activity of intrarenal NOS plays an important role in maintaining glomerular hemodynamics in the canine kidney.

Intrarenal infusion of angiotensin-(1-7) modulates renal functional responses to exogenous angiotensin II in the rat.

In the present study we investigated the possible role of angiotensin-(1-7) [Ang-(1-7)] in modulating renal functional responses to intrarenal (i.e.) infusion of angiotensin II (ANG II) in normotensive anesthetized rats. ANG II (6 ng/min, n = 14) decreased glomerular filtration rate (GFR), renal plasma flow (RPF), absolute and fractional sodium excretion by -24 +/- 5, -25 +/- 6, -44 +/- 6 and -28 +/- 7%, respectively (p < 0.05). i.r. infusion of Ang-(1-7) (50 ng/min, n = 13) did not significantly alter GFR (+6 +/- 4%) but reduced RPF by -19 +/- 7% (p < 0.05). Ang-(1-7) increased absolute and fractional sodium excretion by +36 +/- 6 and +37 +/- 8%, respectively (p < 0.05). Infusion of Ang-(1-7) did not prevent the decreases in GFR and RPF but completely blunted the decreases in absolute (-2 +/- 2%) and fractional sodium excretion (-4 +/- 4%) induced by ANG II (n = 11). Blockade of the Ang-(1-7) receptor by [7-D-Ala]-Ang-(1-7) (5 microg/min, n = 11) significantly decreased GFR, RPF, absolute and fractional sodium excretion by -28 +/- 7, -20 +/- 5, -32 +/- 7 and -24 +/- 4%, respectively (p < 0.05), suggesting that the action of endogenous ANG II is unopposed by compensatory effect of endogenous Ang-(1-7). i.r. infusion of Ang-(1-7) (n = 10) did not alter the effect of Ang-(1-7) receptor blockade on RPF (-21 +/- 6%) but blunted its effects on GFR (+4 +/- 3%) and absolute (+7 +/- 5%) and fractional (+6 +/- 4%) urinary sodium excretion probably by displacing the receptor blocker. While exogenous ANG II during blockade of the Ang-(1-7) receptor and the AT(2) receptor (by PD 123319; 1 microg/min i.r., n = 9) resulted in the same decreases in absolute and fractional sodium excretion (-39 +/- 8 and -38 +/- 6%, respectively, p < 0.05) as did ANG II in the absence of Ang-(1-7) receptor blockade. These results suggest that in normotensive rats high i.r. Ang-(1-7) concentration attenuates the tubular, i.e. sodium reabsorptive effect, but not the vascular effect of exogenous i.r. ANG II. Results obtained during blockade of Ang-(1-7) and of AT(2) receptors imply that AT(2) receptors play a role in tubular sodium reabsorption in the presence of high ANG II concentration.