Estrogen Receptor-α in the Bed Nucleus of the Stria Terminalis Regulates Social Affiliation in Male Prairie Voles (Microtus ochrogaster)

Estrogen receptor alpha (ERα) typically masculinizes male behavior, while low levels of ERα in the medial amygdala (MeA) and the bed nucleus of the stria terminalis (BST) are associated with high levels of male prosocial behavior. In the males of the highly social prairie vole (Microtus ochrogaster), increasing ERα in the MeA inhibited the expression of spontaneous alloparental behavior and produced a preference for novel females. To test for the effects of increased ERα in the BST, a viral vector was used to enhance ERα expression in the BST of adult male prairie voles. Following treatment, adult males were tested for alloparental behavior with 1–3-day-old pups, and for heterosexual social preference and affiliation. Treatment did not affect alloparental behavior as 73% of ERα-BST males and 62.5% of control males were alloparental. Increasing ERα in the BST affected heterosexual affiliation, with ERα-BST males spending significantly less total time in side-by-side contact with females relative to time spent with control males. ERα-BST males did not show a preference for either the familiar or novel female. These findings differed significantly from those reported in ERα-MeA enhanced males, where ERα inhibited alloparental behavior and produced a preference for a novel female. The findings from this study suggest two things: first, that increased ERα in the BST decreases social affiliation and second, that altering ERα in different regions of the social neural circuit differentially impacts the expression of social behavior.     

Effect of varying polyglutamate chain length on the structure and stability of ferricytochrome c

The effect of varying polyglutamate chain length on local and global stability of horse heart ferricytochrome c was studied using scanning calorimetry and spectroscopy methods. Spectral data indicate that polyglutamate chain lengths equal or greater than eight monomer units significantly change the apparent pK(a) for the alkaline transition of cytochrome c. The change in pK(a) is comparable to the value when cytochrome c is complexed with cytochrome bc(1). Glutamate and diglutamate do not significantly alter the temperature transition for cleavage of the Met(80)-heme iron bond of cytochrome c. At low ionic strength, polyglutamates consisting of eight or more glutamate monomers increase midpoint of the temperature transition from 57.3+/-0.2 to 66.9+/-0.2 degrees C. On the other hand, the denaturation temperature of cytochrome c decreases from 85.2+/-0.2 to 68.8+/-0.2 degrees C in the presence of polyglutamates with number of glutamate monomers n >or approximately equal 8. The rate constant for cyanide binding to the heme iron of cytochrome c of cytochrome c-polyglutamate complex also decreases by approximately 42.5% with n>or approximately equal 8. The binding constant for the binding of octaglutamate (m.w. approximately 1000) to cyt c was found to be 1.15 x 10(5) M(-1) at pH 8.0 and low ionic strength. The results indicate that the polyglutamate (n>or approximately equal 8) is able to increase the stability of the methionine sulfur-heme iron bond of cytochrome c in spite of structural differences that weaken the overall stability of the cyt c at neutral and slightly alkaline pH.     

Identification of the hereditary variants of skin melanoma

The identification of hereditary variants of cutaneous melanoma and analysis of the role of hereditary factors and syndromes predisposing to cutaneous melanoma were carried out. The involvement of individual nevus phenotypes in the development of this disease was determined. Based on a survey of recent molecular biological data and our studies, the etiological and genetic heterogeneity of cutaneous melanoma is reported. In relatives of patients with cutaneous melanoma and persons with multiple pigmented nevi, the malignant tumors proved to be differentiated in the direction of the neural crist tissues and/or derivatives of cutaneous mesenchyma. Based on the evidence obtained, the approaches have been developed to formation of risk groups for the purpose of early diagnostics of cutaneous melanoma.     

Subunit analysis of mitochondrial cytochrome c oxidase and cytochrome bc1 by reversed-phase high-performance liquid chromatography

A rapid separation of the ten nuclearly-encoded subunits of mitochondrial cytochrome c oxidase, and ten out of the eleven subunits of cytochrome bc₁, was achieved using a short, 50 mm C₁₈-reversed-phase column. The short column decreased the elution time 4–7 fold while maintaining the same resolution quality. Elution was similar to a previously published protocol, i.e., a water/acetonitrile elution gradient containing trifluoroacetic acid. Isolated subunits were identified by MALDI-TOF. The rapidity of the described method makes it extremely useful for determining the subunit composition of isolated mitochondrial complexes. The method can be used for both analytical and micro-preparative purposes.     

Specific modification of two tryptophans within the nuclear-encoded subunits of bovine cytochrome c oxidase by hydrogen peroxide

Hydrogen peroxide does more than react with the binuclear center of oxidized bovine cytochrome c oxidase and generate the well-characterized "peroxy" and "ferryl" forms. Hydrogen peroxide also inactivates detergent-solubilized cytochrome c oxidase in a time- and concentration-dependent manner. There is a 70-80% decrease of electron-transport activity, peroxidation of bound cardiolipin, modification of two nuclear-encoded subunits (IV and VIIc), and dissociation of approximately 60% of subunits VIa and VIIa. Modification of subunit VIIc and dissociation of subunit VIIa are coupled events that probably are responsible for the inactivation of cytochrome c oxidase. When cytochrome c oxidase is exposed to 500 microM hydrogen peroxide for 30 min at pH 7.4 and room temperature, subunits IV (modified up to 20%) and VIIc (modified up to 70%) each have an increased mass of 16 Da as detected by matrix-assisted laser desorption/ionization time-of-flight mass spectrometry and electrospray ionization mass spectrometry. In each case, the increased mass is caused by oxidation of a tryptophan (Trp19 within subunit VIIc and Trp48 within subunit IV), almost certainly due to formation of hydroxytryptophan. We conclude that hydrogen peroxide-induced oxidation of tryptophan and cardiolipin proceeds via the binuclear center since both modifications are prevented if the binuclear center is first blocked with cyanide. Bound cardiolipin and oxidized tryptophans are localized relatively far from the binuclear center (30-60 A); therefore, oxidation probably occurs by migration of a free radical generated at the binuclear center to these distal reaction sites.     

A cis-acting element that directs circular adeno-associated virus replication and packaging

A novel pathway of adeno-associated virus (AAV) replication marked by the assembly of circular monomer duplex intermediates (cAAV) has been recently discovered. In the present report we identify a single AD domain of the inverted terminal repeat as a minimal origin of cAAV replication. A small internal palindrome (BB'), necessary for optimal Rep-inverted terminal repeat interaction, does not contribute to the efficiency of cAAV replication, while the terminal resolution site is an essential cis-acting element. Furthermore, recombinant cAAV vectors that encompass only the AD domain replicate exclusively in a circular form and no detectable linear duplex replicative intermediates are generated, suggesting that both pathways of AAV replication are independent and can be separated. In addition, we show that cAAVs are efficient templates for encapsidation of single-stranded DNA genomes, an observation that assigns a biological role for these novel replication species. Together, these findings shed new light on the current model of AAV replication and packaging.     

Influence of reduction of heme a and Cu(A) on the oxidized catalytic center of cytochrome c oxidase: insight from organic solvents

Purified bovine heart cytochrome c oxidase (CcO) has been extracted from aqueous solution into hexane in the presence of phospholipids and calcium ions. In extracts, CcO is in the so-called "slow" form and probably situated in reverse micelles. At low water:phospholipid molar ratios, electron transfer from reduced heme a and Cu(A) to the catalytic center is inhibited and both heme a3 and Cu(B) remain in the oxidized state. The rate of binding of cyanide to heme a3 in this oxidized catalytic center is, however, dependent on the redox state of heme a and Cu(A). When heme a and Cu(A) are reduced, the rate is increased 20-fold compared to the rate when these two centers are oxidized. The enhanced rate of binding of cyanide to heme a3 is explained by the destabilization of an intrinsic ligand, located at the catalytic site, that is triggered by the reduction of heme a and Cu(A).     

Cholate-induced dimerization of detergent- or phospholipid-solubilized bovine cytochrome C oxidase

Bovine heart cytochrome c oxidase (CcO), solubilized by either nonionic detergents or phospholipids, completely dimerizes upon the addition of bile salts, e.g., sodium cholate, sodium deoxycholate, or CHAPS. Bile salt induced dimerization occurs whether dodecyl maltoside, decyl maltoside, or Triton X-100 is the primary solubilizing detergent or the enzyme is dispersed in phosphatidylcholine, phosphatidylethanolamine, or mixtures thereof. In each case, complete CcO dimerization can be verified by sedimentation velocity and sedimentation equilibrium after correction for bound detergent and/or phospholipid. The relative concentration of the bile salt is critical for production of homogeneous, dimeric CcO. For example, enzyme solubilized by 2 mM detergent requires an equal molar concentration of sodium cholate. Similarly, enzyme dispersed in 20 mM phospholipid requires 50 mM sodium cholate, concentrations that are commonly used to reconstitute CcO into small unilamellar vesicles. Bile salts do more than just stabilize dimeric CcO and prevent detergent-induced dissociation into monomers. They are able to completely reverse detergent-induced monomerization and cause completely monomeric CcO to reassociate. Dimeric CcO so generated is no more stable than the original complex and easily dissociates into monomers if the bile salt is removed. The dimerization process is dependent upon a full complement of subunits; e.g., if subunits VIa and VIb are removed, the resulting monomeric CcO will not reassociate upon the addition of sodium cholate. These results support four important consequences: (1) dissociation of dimeric CcO into monomers is reversible; (2) stable dimers can be produced under solution conditions; (3) dimers can be stabilized even at relatively high pH and low enzyme concentration; and (4) subunits VIa and VIb are required for dimerization.     

Contribution of peroxidized cardiolipin to inactivation of bovine heart cytochrome c oxidase

The lipid-soluble peroxides, tert-butyl hydroperoxide and peroxidized cardiolipin, each react with bovine cytochrome c oxidase and cause a loss of electron-transport activity. Coinciding with loss of activity is oxidation of Trp19 and Trp48 within subunits VIIc and IV, and partial dissociation of subunits VIa and VIIa. tert-Butyl hydroperoxide initiates these structural and functional changes of cytochrome c oxidase by three mechanisms: (1) radical generation at the binuclear center; (2) direct oxidation of Trp19 and Trp48; and (3) peroxidation of bound cardiolipin. All three mechanisms contribute to inactivation since blocking a single mechanism only partially prevents oxidative damage. The first mechanism is similar to that described for hydrogen peroxide [Biochemistry43:1003-1009; 2004], while the second and third mechanism are unique to organic hydroperoxides. Peroxidized cardiolipin inactivates cytochrome c oxidase in the absence of tert-butyl hydroperoxide and oxidizes the same tryptophans within the nuclear-encoded subunits. Peroxidized cardiolipin also inactivates cardiolipin-free cytochrome c oxidase rather than restoring full activity. Cardiolipin-free cytochrome c oxidase, although it does not contain cardiolipin, is still inactivated by tert-butyl hydroperoxide, indicating that the other oxidation products contribute to the inactivation of cytochrome c oxidase. We conclude that both peroxidized cardiolipin and tert-butyl hydroperoxide react with and triggers a cascade of structural alterations within cytochrome c oxidase. The summation of these events leads to cytochrome c oxidase inactivation.