Increased warm water intrusions could cause mass loss in East Antarctica during the next 200 years.

The East Antarctic Ice Sheet (EAIS) is currently surrounded by relatively cool water, but climatic shifts have the potential to increase basal melting via intrusions of warm modified Circumpolar Deep Water (mCDW) onto the continental shelf. Here we use an ice sheet model to show that under the current ocean regime, with only limited intrusions of mCDW, the EAIS will likely gain mass over the next 200 years due to the increased precipitation from a warming atmosphere outweighing increased ice discharge due to ice-shelf melting. However, if the ocean regime were to become dominated by greater mCDW intrusions, the EAIS would have a negative mass balance, contributing up to 48 mm of SLE over this time period. Our modelling finds George V Land to be particularly at risk to increased ocean induced melting. With warmer oceans, we also find that a mid range RCP4.5 emissions scenario is likely to result in a more negative mass balance than a high RCP8.5 emissions scenario, as the relative difference between increased precipitation due to a warming atmosphere and increased ice discharge due to a warming ocean is more negative in the mid range RCP4.5 emission scenario.

Rapid, climate-driven changes in outlet glaciers on the Pacific coast of East Antarctica.

Observations of ocean-terminating outlet glaciers in Greenland and West Antarctica indicate that their contribution to sea level is accelerating as a result of increased velocity, thinning and retreat. Thinning has also been reported along the margin of the much larger East Antarctic ice sheet, but whether glaciers are advancing or retreating there is largely unknown, and there has been no attempt to place such changes in the context of localized mass loss or climatic or oceanic forcing. Here we present multidecadal trends in the terminus position of 175 ocean-terminating outlet glaciers along 5,400 kilometres of the margin of the East Antarctic ice sheet, and reveal widespread and synchronous changes. Despite large fluctuations between glaciers--linked to their size--three epochal patterns emerged: 63 per cent of glaciers retreated from 1974 to 1990, 72 per cent advanced from 1990 to 2000, and 58 per cent advanced from 2000 to 2010. These trends were most pronounced along the warmer western South Pacific coast, whereas glaciers along the cooler Ross Sea coast experienced no significant changes. We find that glacier change along the Pacific coast is consistent with a rapid and coherent response to air temperature and sea-ice trends, linked through the dominant mode of atmospheric variability (the Southern Annular Mode). We conclude that parts of the world's largest ice sheet may be more vulnerable to external forcing than recognized previously.

Synchronization of the three reaction centers within carbamoyl phosphate synthetase.

Carbamoyl phosphate synthetase from E. coli catalyzes the synthesis of carbamoyl phosphate through a series of four reactions occurring at three active sites connected by a molecular tunnel of 100 A. To understand the mechanism for coordination and synchronization among the active sites, the pre-steady-state time courses for the formation of phosphate, ADP, glutamate, and carbamoyl phosphate were determined. When bicarbonate and ATP were rapidly mixed with CPS, a stoichiometric burst of acid-labile phosphate and ADP was observed with a formation rate constant of 1100 min(-)(1). The burst phase was followed by a linear steady-state phase with a rate constant of 12 min(-)(1). When glutamine or ammonia was added to the initial reaction mixture, the magnitude and the rate of formation of the burst phase for either phosphate or ADP were unchanged, but the rate constant for the linear steady-state phase increased to an average value of 78 min(-)(1). These results demonstrate that the initial phosphorylation of bicarbonate is independent of the binding or hydrolysis of glutamine. The pre-steady-state time course for the hydrolysis of glutamine in the absence of ATP exhibited a burst of glutamate formation with a rate constant of 4 min(-)(1) when the reaction was quenched with base. In the presence of ATP and bicarbonate, the rate constant for the formation of the burst of glutamate was 1100 min(-)(1). The hydrolysis of ATP thus enhanced the hydrolysis of glutamine by a factor of 275, but there was no effect by glutamine on the initial phosphorylation of bicarbonate. The pre-steady-state time course for the formation of carbamoyl phosphate was linear with an overall rate constant of 72 min(-)(1). The absence of an initial burst of carbamoyl phosphate formation eliminates product release as a rate-determining step for CPS. Overall, these results have been interpreted to be consistent with a mechanism whereby the phosphorylation of bicarbonate serves as the initial trigger for the rest of the reaction cascade. The formation of the carboxy phosphate intermediate within the large subunit must induce a conformational change to the active site of the small subunit that enhances the hydrolysis of glutamine. Thus, ammonia is not released into the molecular tunnel until the activated bicarbonate is ready to form carbamate. The rate-limiting step for the steady-state assembly of carbamoyl phosphate is either the formation, migration, or phosphorylation of the carbamate intermediate.

Regulatory control of the amidotransferase domain of carbamoyl phosphate synthetase.

Carbamoyl phosphate synthetase catalyzes the hydrolysis of glutamine by the nucleophilic attack of an active site cysteine residue through a mechanism that requires the formation of a gamma-glutamyl thioester intermediate. The steady-state mole fraction of the thioester intermediate was determined to be 0.23 in the presence and absence of ATP and bicarbonate. The kinetics of formation and hydrolysis of the gamma-glutamyl thioester intermediate during CPS catalyzed hydrolysis of glutamine were determined. When ATP and bicarbonate are added to CPS and glutamine, the kcat for glutamine hydrolysis increases from 0.17 to 150 min-1. The observed rate constant for thioester intermediate formation increases from 18 to 580 min-1, and the microscopic rate constant for hydrolysis of the intermediate increases from 0.15 to 460 min-1. These results demonstrate the kinetic competence of the thioester intermediate during glutamine hydrolysis. The rate-determining step changes from the hydrolysis of the intermediate when ATP and bicarbonate are absent to the formation of the intermediate upon the addition of ATP and bicarbonate. The 3 order of magnitude increase in the rate of glutamine hydrolysis upon the addition of ATP and bicarbonate is indicative of the allosteric communication between two of the three reaction centers of CPS. These sites are physically separated by approximately 45 A.

Mechanism-based inactivation of phosphotriesterase by reaction of a critical histidine with a ketene intermediate.

Five alkynyl phosphate esters have been synthesized as probes of the active site structure of phosphotriesterase. These compounds have the potential to be converted by the enzyme to a highly reactive ketene intermediate which can then react with an active site nucleophile causing irreversible inhibition of the enzyme by formation of an inactive covalent adduct. All five compounds completely inactivate enzyme function in less than 15 s at pH 7.0. The partition rations of 1-hexynyl diethyl phosphate (I), 1-propynyl diethyl phosphate (II), 1-hexynyl diphenyl phosphate (III), 1-hexynyl dimethyl phosphate (IV), and ethynyl diethyl phosphate (V) fall in the range between 480 and 1700; thus, all five alkynyl phosphate esters work equally well as inactivators despite the differences in their structures. The rate constants for enzyme inactivation, kinact, are 1.7 s-1 with I, 1.3 s-1 with II, and 0.12 s-1 with IV. They compare well with the kcat for the Co-substituted phosphotriesterase; hence these compounds are good substrates. The stoichiometry of inhibitor bound to protein is 1:1, as determined by inactivation of the enzyme using the radiolabeled compound [3-14C]-1-propynyl diethyl phosphate. Addition of an exogenous nucleophile, azide, did not protect phosphotriesterase from being inactivated by the alkynyl phosphate esters, suggesting that the reactive intermediate produced from the inhibitor is not released from the enzyme surface prior to covalent labeling of the protein. Chemical and spectroscopic evidence suggests that a histidine residue is modified in the inactivation reaction. The inactivated phosphotriesterase can be reactivated by increasing the pH of the protein solution. N-Acylimidazoles are known to be easily hydrolyzed at alkaline pH values.(ABSTRACT TRUNCATED AT 250 WORDS)

Differential roles for three conserved histidine residues within the large subunit of carbamoyl phosphate synthetase.

Three conserved histidine residues, His-243, His-781, and His-788, located within the large subunit of carbamoyl phosphate synthetase from Escherichia coli were identified by sequence identity comparisons. These three histidine residues were individually mutated to asparagine residues. The H243N mutant enzyme was found to be critical for carbamoyl phosphate synthesis as the mutant protein was unable to synthesize carbamoyl phosphate at a significant rate (< 1/1500). By analysis of the effects of this mutation on the partial reactions catalyzed by CPS, it was determined that this mutation blocked the formation of the carbamate intermediate from carboxyphosphate and ammonia. The H781N mutant enzyme had an order of magnitude reduction for both the rate of carbamoyl phosphate formation and ATP synthesis which is consistent with the proposal that the carboxyl-terminal half of the large subunit is primarily involved in the phosphorylation of the putative carbamate intermediate. This mutation also reduced the effects of the allosteric activator ornithine on the Km parameters for ATP in the overall biosynthetic reaction and ADP in the ATP synthesis reaction. The H788N mutant enzyme is a functional protein which maintains the ability to synthesize carbamoyl phosphate at a rate comparable to that of the wild-type enzyme. The effects of this mutation are 10-fold reductions of the ATP synthetase and the bicarbonate-dependent ATPase activities with substantial increases in the Km values for ATP in the full biosynthetic reaction and for ADP in the ATP synthesis reaction.(ABSTRACT TRUNCATED AT 250 WORDS)