We have generated a transgenic model consisting of both the human renin and human angiotensinogen genes to study further the role played by the renin-angiotensin system in regulating arterial pressure. Transgenic mice containing either gene alone were normotensive, whereas mice containing both genes were chronically hypertensive. Plasma renin activity and plasma angiotensin II levels were both markedly elevated in the double transgenic mice compared with either single transgenic or nontransgenic controls. The elevation in blood pressure caused by the human transgenes was independent of the genotype at the endogenous renin locus and was equal in mice homozygous for the Ren-1 c allele or in mice containing one copy each of Ren-1 c , Ren-1 d , or Ren-2. Chronic overproduction of angiotensin II in the double transgenic mice resulted in a resetting of the baroreflex control of heart rate to a higher pressure without significantly changing the gain or sensitivity of the reflex. Moreover, this change was not due to the effects of elevated pressure itself since angiotensin-converting enzyme inhibition had minimal effects on the baroreflex in spontaneously hypertensive BPH-2 control mice, which exhibit non-renindependent hypertension. This double transgenic model should provide an excellent tool for further studies on the mechanisms of hypertension initiated by the renin-angiotensin system. ( J. Clin. Invest. 1996. 97:1047-1055.)
We have determined a 2.1 A crystal structure for human mitochondrial ClpP (hClpP), the proteolytic component of the ATP-dependent ClpXP protease. HClpP has a structure similar to that of the bacterial enzyme, with the proteolytic active sites sequestered within an aqueous chamber formed by face-to-face assembly of the two heptameric rings. The hydrophobic N-terminal peptides of the subunits are bound within the narrow (12 A) axial channel, positioned to interact with unfolded substrates translocated there by the associated ClpX chaperone. Mutation or deletion of these residues causes a drastic decrease in ClpX-mediated protein and peptide degradation. Residues 8-16 form a mobile loop that extends above the ring surface and is also required for activity. The 28 amino acid C-terminal domain, a unique feature of mammalian ClpP proteins, lies on the periphery of the ring, with its proximal portion forming a loop that extends out from the ring surface. Residues at the start of the C-terminal domain impinge on subunit interfaces within the ring and affect heptamer assembly and stability. We propose that the N-terminal peptide of ClpP is a structural component of the substrate translocation channel and may play an important functional role as well.
The amyloid- (A) peptide, which likely plays a key role in Alzheimer disease, is derived from the amyloid- precursor protein (APP) through consecutive proteolytic cleavages by -site APP-cleaving enzyme and ␥-secretase. Unexpectedly ␥-secretase inhibitors can increase the secretion of A peptides under some circumstances. This "A rise" phenomenon, the same inhibitor causing an increase in A at low concentrations but inhibition at higher concentrations, has been widely observed. Here we show that the A rise depends on the -secretase-derived C-terminal fragment of APP (CTF) or C99 levels with low levels causing rises. In contrast, the N-terminally truncated form of A, known as "p3," formed by ␣-secretase cleavage, did not exhibit a rise. In addition to the A rise, low CTF or C99 expression decreased ␥-secretase inhibitor potency. This "potency shift" may be explained by the relatively high enzyme to substrate ratio under conditions of low substrate because increased concentrations of inhibitor would be necessary to affect substrate turnover. Consistent with this hypothesis, ␥-secretase inhibitor radioligand occupancy studies showed that a high level of occupancy was correlated with inhibition of A under conditions of low substrate expression. The A rise was also observed in rat brain after dosing with the ␥-secretase inhibitor BMS-299897. The A rise and potency shift are therefore relevant factors in the development of ␥-secretase inhibitors and can be evaluated using appropriate choices of animal and cell culture models. Hypothetical mechanisms for the A rise, including the "incomplete processing" and endocytic models, are discussed.Evidence suggests that the amyloid- (A) 9 peptide plays a key role in Alzheimer disease. A is generated by proteolytic processing of the amyloid- precursor protein (APP) through consecutive cleavages by the -site APP-cleaving enzyme (BACE) and ␥-secretase. APP is cleaved by BACE to form a -secretase-derived C-terminal fragment of APP (CTF), which undergoes further cleavage by ␥-secretase to form A. In addition, APP is cleaved by ␣-secretase to form ␣CTF, which undergoes ␥-secretase cleavage to produce an N-terminally truncated form of A known as "p3." Using the conventional amino acid numbering of A, BACE cleavage leads to A peptides with N-terminal ends at positions 1 and 11, whereas ␣-secretase leads to p3 peptides with an N-terminal end at position 17. Cleavage of CTF and ␣CTF by ␥-secretase produces a mixture of different C termini in the resulting A and p3 peptides. For example, the predominant ␥-secretase cleavage of CTFs at position 40 produces A-(1-40) and A-(11-40), whereas other ␥-secretase cleavage sites produce a range of less abundant A peptides, such as the disease-associated A-(1-42) (1, 2).
The ClpAP protease from Escherichia coli consists of the ATP-binding regulatory component, ClpA (subunit Mr 84 165), and the proteolytic component, ClpP (subunit Mr 21 563). Our hydrodynamic studies demonstrate that the predominant forms of these proteins in solution correspond to those observed by electron microscopy. ClpP and proClpP(SA), which in electron micrographs appear to have subunits arranged in rings of seven subunits, were found by ultracentrifugation to have s20,w values of 12.2 and 13.2 S and molecular weights of 300 000 and 324 000 +/- 3000, respectively, indicating that the native form of each consists of two such rings. The two intact rings of ClpP were separated in the presence of >/= 0.1 M sulfate at low temperatures, suggesting that ring-ring contacts are polar in nature and more easily disrupted than subunit contacts within individual rings. Sedimentation equilibrium analysis indicated that ClpA purified without nucleotide exists as an equilibrium mixture of monomers and dimers with Ka = (1.0 +/- 0.2) x 10(5) M-1 and that, upon addition of MgATP or adenosine 5'-O-(3-thiotriphosphate), ClpA subunits associated to a form with Mr 505 000 +/- 5000, consistent with the hexameric structure seen by electron microscopy. Sedimentation velocity and gel-filtration analysis showed that the nucleotide-promoted hexamer of ClpA (s20,w = 17.2 S) binds tightly to ClpP producing species with s20,w values of 21 and 27 S (f/f0 = 1.5 and 1.8, respectively), consistent with electron micrographs of ClpAP that show a single tetradecamer of ClpP associated with either one or two ClpA hexamers [Kessel et al. (1995) J. Mol. Biol. 250, 587-594]. Under assay conditions in the presence of ATP and Mg2+, the apparent dissociation constant of hexameric ClpA and tetradecameric ClpP was approximately 4 +/- 2 nM. By the method of continuous variation, the optimal ratio of ClpA to ClpP in the active complex was 2:1. The specific activities of limiting ClpA and ClpP determined in the presence of an excess of the other component indicated that the second molecule of ClpA provides very little additional activation of ClpP.
Pediatric patients account for approximately 10% of all CSH admissions in Afghanistan and Iraq. Burns and penetrating head injury account for the majority of pediatric mortality at the CSH.
Our results suggest that DP using simulation is associated with improvements in NRP performance and support the use of DP using simulation in NRP training.
Increases in woody plant cover in savanna grassland environments have been reported on globally for over 50 years and are generally perceived as a threat to rangeland productivity and biodiversity. Despite this, few attempts have been made to estimate the extent of woodland increase at a national scale, principally due to technical constraints such as availability of appropriate remote sensing products. In this study, we aimed to measure the extent to which woodlands have replaced grasslands in South Africa's grassy biomes. We use multiseason Landsat data in conjunction with satellite L-band radar backscatter data to estimate the extent of woodlands and grasslands in 1990 and 2013. The method employed allows for a unique, nationwide measurement of transitions between grassland and woodland classes in recent decades. We estimate that during the 23-year study period, woodlands have replaced grasslands over ~57 000 km and conversely that grasslands have replaced woodlands over ~30 000 km , a net increase in the extent of woodland of ~27 000 km and an annual increase of 0.22%. The changes varied markedly across the country; areas receiving over 500 mm mean annual precipitation showed higher rates of woodland expansion than regions receiving <500 mm (0.31% yr and 0.11% yr , respectively). Protected areas with elephants showed clear loss of woodlands (-0.43% yr ), while commercial rangelands and traditional rangelands showed increases in woodland extent (>0.19% yr ). The woodland change map presented here provides a unique opportunity to test the numerous models of woody plant encroachment at a national/regional scale.
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