Antarctic teleosts with and without hemoglobin behaviorally mitigate deleterious effects of acute environmental warming.

Recent studies forecast that many ectothermic animals, especially aquatic stenotherms, may not be able to thrive or even survive predicted climate change. These projections, however, generally do not call much attention to the role of behavior, an essential thermoregulatory mechanism of many ectotherms. Here we characterize species-specific locomotor and respiratory responses to acute ambient warming in two highly stenothermic Antarctic Notothenioid fishes, one of which (Chaenocephalus aceratus) lacks hemoglobin and appears to be less tolerant to thermal stress as compared to the other (Notothenia coriiceps), which expresses hemoglobin. At the onset of ambient warming, both species perform distinct locomotor maneuvers that appear to include avoidance reactions. In response to unavoidable progressive hyperthermia, fishes demonstrate a range of species-specific maneuvers, all of which appear to provide some mitigation of the deleterious effects of obligatory thermoconformation and to compensate for increasing metabolic demand by enhancing the efficacy of branchial respiration. As temperature continues to rise, Chaenocephalus aceratus supplements these behaviors with intensive pectoral fin fanning which may facilitate cutaneous respiration through its scaleless integument, and Notothenia coriiceps manifests respiratory-locomotor coupling during repetitive startle-like maneuvers which may further augment gill ventilation. The latter behaviors, found only in Notothenia coriiceps, have highly stereotyped appearance resembling Fixed Action Pattern sequences. Altogether, this behavioral flexibility could contribute to the reduction of the detrimental effects of acute thermal stress within a limited thermal range. In an ecologically relevant setting, this may enable efficient thermoregulation of fishes by habitat selection, thus facilitating their resilience in persistent environmental change.

Mechanisms of interactions of the nucleotide cofactor with the RepA protein of plasmid RSF1010. Binding dynamics studied using the fluorescence stopped-flow method.

The dynamics of the nucleotide binding to a single, noninteracting nucleotide-binding site of the hexameric helicase RepA protein of plasmid RSF1010 has been examined, using the fluorescence stopped-flow method. The experiments have been performed with fluorescent analogues of ATP and ADP, TNP-ATP and TNP-ADP, respectively. In the presence of Mg(2+), the association of the cofactors proceeds as a sequential three-step process [Formula: see text] The sequential nature of the mechanism indicates the lack of significant conformational equilibria of the helicase prior to nucleotide binding. The major conformational change of the RepA helicase-nucleotide complex occurs in the formation of (H-N)(2), which is characterized by a very high value of the partial equilibrium constant and large positive changes in the apparent enthalpy and entropy. Strong stabilizing interactions between subunits of the RepA hexamer contribute to the observed dynamics and energetics of the internal transitions of the formed complexes. Magnesium cations mediate the efficient and fast conformational transitions of the protein, in a manner independent of the structure of the cofactor phosphate group. The ssDNA bound to the enzyme preferentially selects a single intermediate of the RepA-ATP analogue complex, (H-N)(2), while the DNA has no effect on the intermediates of the RepA-ADP complex. Allosteric interactions between the nucleotide- and DNA-binding site are established in the initial stages of formation of the complex. Moreover, in the presence of the single-stranded DNA, all the transitions in the nucleotide binding to the helicase become sensitive to the structure of the phosphate group of the cofactor.

Dynamics of the ssDNA recognition by the RepA hexameric helicase of plasmid RSF1010: analyses using fluorescence stopped-flow intensity and anisotropy methods.

The kinetic mechanism of the single-stranded DNA (ssDNA) recognition by the RepA hexameric replicative helicase of the plasmid RSF1010 and the nature of formed intermediates, in the presence of the ATP nonhydrolyzable analog, beta,gamma-imidoadenosine-5'-triphosphate (AMP-PNP), have been examined, using the fluorescence intensity and anisotropy stopped-flow and analytical ultracentrifugation methods. Association of the RepA hexamer with the ssDNA oligomers that engage the total DNA-binding site and exclusively the strong DNA-binding subsite is a minimum four-step mechanism [formula: see text]. Extreme stability of the RepA hexamer precludes any disintegration of its structure, and the sequential character of the mechanism indicates that the enzyme exists in a predominantly single conformation prior to the association with the nucleic acid. Moreover, the hexameric helicase possesses a DNA-binding site located outside its cross channel. The reaction steps have dramatically different dynamics, with rate constants differing by 2-3 orders of magnitude. Such behavior indicates a very diverse nature of the observed transitions, which comprises binding steps and large conformational transitions of the helicase, including local opening of the hexameric structure. Steady-state fluorescence anisotropies of intermediates indicate that the entry of the DNA into the cross channel is initiated from the 5' end of the bound nucleic acid. The global structure of the tertiary complex RepA-ssDNA-AMP-PNP is very different from the structure of the binary complex RepA-AMP-PNP, indicating that, in equilibrium, the RepA hexamer-ssDNA-AMP-PNP complex exists as a mixture of partially open states.

Site specificity of agonist-induced opening and desensitization of the Torpedo californica nicotinic acetylcholine receptor.

Agonist-binding kinetics to the nicotinic acetylcholine receptor (AChR) from Torpedo californica were measured using sequential-mixing stopped-flow fluorescence methods to determine the contribution of each individual site to agonist-induced opening and desensitization. Timed dansyl-C6-choline (DC6C) binding followed by its dissociation upon mixing with high, competing agonist concentrations revealed four kinetic components: an initial, fast fluorescence decay, followed by a transient increase, and then two characteristic decays that reflect dissociation from the desensitized agonist sites. The transient increase resulted from DC6C binding to the open-channel based on its prevention by proadifen, a noncompetitive antagonist. Further characterization of DC6C channel binding by the inhibition of [3H]phencyclidine binding and by equilibrium measurements of DC6C fluorescence yielded KD values of 2-4 microM for the desensitized AChR and approximately 600 microM for the closed state. At this site, DC6C displayed a strongly blue-shifted emission spectrum, higher intrinsic fluorescence, and weaker energy transfer from tryptophans than when bound to either agonist site. The initial, fast fluorescence decay was assigned to DC6C dissociation from the alphadelta site of the AChR in its closed conformation, on the basis of inhibition with the site-selective antagonists d-tubocurarine and alpha-conotoxin MI. Fast decay amplitude data indicated an apparent affinity of 0.9 microM for the closed-state alphadelta site; the closed-state alphagamma-site affinity is inferred to be near 100 microM. These values and the known affinities for the desensitized conformation show that the alphagamma site drives AChR desensitization to a approximately 40-fold greater extent than the alphadelta site, undergoes energetically larger conformational changes, and is the primary determinant of agonist potency.

Site-selective agonist binding to the nicotinic acetylcholine receptor from Torpedo californica.

Fluorescent energy transfer measurements of dansyl-C6-choline binding to the nicotinic acetylcholine receptor (AChR) from Torpedo californica were used to determine binding characteristics of the alpha gamma and alpha delta binding sites. Equilibrium binding measurements show that the alpha gamma site has a lower fluorescence than the alpha delta site; the emission difference is due to differences in the intrinsic fluorescence of the bound fluorophores rather than differences in energy transfer at the two sites. Stopped-flow fluorescence kinetics showed that dissociation of dansyl-C6-choline from the AChR in the desensitized conformation occurs 5-10-fold faster from the alpha gamma site than from the alpha delta site. The dissociation rates are robust for distinct protein preparations, in the presence of noncompetitive antagonists, and over a broad range of ionic strengths. Equilibrium fluorescent binding measurements show that dansyl-C6-choline binds with higher affinity to the alpha delta site (K = 3 nM) than to the alpha gamma site (K = 9 nM) when the AChR is desensitized. Similar affinity differences were observed for acetylcholine itself. The distinct dissociation rates permit the extent of desensitization to be measured at each site during the time course of binding. This sequential mixing method of measuring the desensitized state population at each agonist site can be applied to study the mechanism of AChR activation and subsequent desensitization in detail.

Effect of molecular crowding on self-association of phosphorylase kinase and its interaction with phosphorylase b and glycogen.

Self-association of phosphorylase kinase (PhK) and its interaction with glycogen (M=5500 kDa) and phosphorylase b (Phb) has been studied using analytical ultracentrifugation and turbidimetry under the conditions of molecular crowding arising from the presence of high concentrations of osmolytes. In accordance with the predictions of the molecular crowding theory, trimethylamine N-oxide (TMAO) and betaine greatly favor self-association of PhK induced by Mg2+ and Ca2+ and PhK interaction with glycogen. In contrast, proline suppresses these processes, probably, due to its specific interaction with PhK. All osmolytes tested prevented the complex formation between PhK and its physiological substrate, Phb. The specific interactions of PhK and Phb with glycogen, in the living cell, presumably is a factor allowing the negative effect of crowding on the recognition of Phb by PhK to be overcome.