Relationship between superoxide anion radical generation and aging in the housefly, Musca domestica

The objective of this study was to elucidate the possible cause of increased oxidative stress observed in the adult housefly during aging. The hypothesis that increased production of oxygen radicals may be a cause of the increased oxidative stress was tested by comparison of 8-day and 15-day old flies, which represent the stage of full maturation and the beginning of the dying phase, respectively. Rates of both antimycin A-resistant respiration of isolated mitochondria and O2 generation at ubiquinone-cytochrome b site by submitochondrial particles increased during aging and were associated with life expectancy of flies. Flies destined to die earlier than their cohorts of the same age exhibited a relatively higher rate of O2- production. Age-related increase in O2- generation was not associated with corresponding changes in ubiquinone content of mitochondria.     

Glutamine synthetase in the phloem plays a major role in controlling proline production

To inhibit expression specifically in the phloem, a 274-bp fragment of a cDNA (Gln1-5) encoding cytosolic glutamine synthetase (GS1) from tobacco was placed in the antisense orientation downstream of the cytosolic Cu/Zn superoxide dismutase promoter of Nicotiana plumbaginifolia. After Agrobacterium-mediated transformation, two transgenic N. tabacum lines exhibiting reduced levels of GS1 mRNA and GS activity in midribs, stems, and roots were obtained. Immunogold labeling experiments allowed us to verify that the GS protein content was markedly decreased in the phloem companion cells of transformed plants. Moreover, a general decrease in proline content in the transgenic plants in comparison with wild-type tobacco was observed when plants were forced to assimilate large amounts of ammonium. In contrast, no major changes in the concentration of amino acids used for nitrogen transport were apparent. A (15)NH(4)(+)-labeling kinetic over a 48-hr period confirmed that in leaves of transgenic plants, the decrease in proline production was directly related to glutamine availability. After 2 weeks of salt treatment, the transgenic plants had a pronounced stress phenotype, consisting of wilting and bleaching in the older leaves. We conclude that GS in the phloem plays a major role in regulating proline production consistent with the function of proline as a nitrogen source and as a key metabolite synthesized in response to water stress.     

Pheomelanin as a Binding Site for Drugs and Chemicals

Certain drugs and chemicals, such as chloroquine, chlorpromazine, and 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine (MPTP), are bound to melanin and retained in pigment cells for long periods. This specific retention in pigmented tissues can cause adverse effects in the skin, eye, inner ear, and pigmented nerve cells of the substantia nigra of the brain. To date, all studies have been focused on eu- and neuromelanin. In the present study, we show that chloroquine, chlorpromazine, chlomipramine, paraquat, acridine orange, and nickel, which are bound to eumelanin, also bind to synthetic pheomelanin, but the binding to pheomelanin is lower. The binding varied with the cysteine content and pH, and the results indicate that the binding is complex and includes ionic interactions. In addition, we have shown that these substances also bind to synthetic thiourea-containing melanin, but to quite a low extent. We also present a microautoradiographic study on the binding of ¹⁴C-chloroquine to natural pheomelanin in vivo in yellow mice C57BL (A^y/a). Black (C57/BL) and albino (NMRI) mice were used as controls. The autoradiography demonstrated a pronounced uptake of chloroquine in the hair follicles and the dermal melanocytes in the ear of yellow mice, which was comparable to the corresponding accumulation of label in black mice. In the albino mouse, the uptake was lower and more homogeneously distributed in the skin. These results suggest that the toxicologi-cal risks of melanin-related adverse effects are applicable to persons with a high content of pheomelanin in the skin and hair.     

Interstitial cell heterogeneity in rat testes. II. Purification of cells by Percoll and metrizamide gradient centrifugation with preferential localization of gonadotropin binding sites in light cell fraction and hormone-induced steroidogenesis in heavier cell fraction

The ability of 125I-labeled human chorionic gonadotropin (125I-labeled hCG) to bind and stimulate steroidogenesis was studied in light cells (density, 1.053-1.065 g/cm3) and heavier cells (density, 1.090-1.110 g/cm3) purified from collagenase-dispersed rat testicular interstitial cells by unit gravity sedimentation (Bhalla, V.K., Rajan, V.P., Burgett, A.C., and Sohal, G.S. (1987) J. Biol. Chem. 262, 5313-5321). Preferential localization of gonadotropin binding sites was demonstrated on light cells, and the heavier cells produced testosterone in response to hCG without occupancy of high affinity (Kd = 2.02 X 10(-10) M) binding sites. In this study, established methods for interstitial cell purification involving gradient centrifugation were utilized to demonstrate the cell heterogeneity. Light cells bound hCG with high affinity (Kd = 3 X 10(-10) M) without manifestation of steroidogenic response. The heavier cells responded to hCG with elicitation of steroidogenesis, but the occupancy was negligible. Stimulation of steroidogenesis by hCG in heavier cells was dose and time dependent. Dibutyryl and bromo cyclic AMP (1 mM) also promoted steroidogenesis comparable to a level stimulated by the tropic hormone (700% stimulation). The concept of spare receptors was tested in purified cell fractions. Upon cell purification, no saturable high affinity binding sites were observed in the heavier cell fraction. Autoradiographic analyses at the electron microscopical level supported this conclusion. Our data suggest that target cell activation is not preceded by hormone occupancy of high affinity binding sites. A model for defining the functional domains of the physiological receptor for hCG is presented.     

SV40 large T antigen is modified with O-linked N-acetylglucosamine but not with other forms of glycosylation

SV40 large T antigen has been reported to be modified with several different sugars including N-acetylglucosamine, galactose, and mannose. In this report we have reexamined the glycosylation of T antigen and found that while we could detect modification with N-acetylglucosamine, we could not detect any other sugars on the protein. Surprisingly, even though [3H]galactose could be metabolically incorporated into the protein, analysis showed that all of the radioactivity in T antigen had been converted to other species. The N-acetylglucosamine was demonstrated to be linked to the protein in the form of O-linked N- acetylglucosamine, the best characterized form of nuclear and cytoplasmic glycosylation in mammalian systems. We have localized the major site of glycosylation to the amino terminal portion of the molecule. Analysis of mutated T antigen where serines 111/112 were substituted with alanine suggest that these residues constitute a glycosylation site on the protein. These two serines fall within a typical O-linked N-acetylglucosamine glycosylation site (PSS) and are also known to be phosphorylated. Thus, it is likely that competition between phosphorylation and glycosylation occurs at this site.      

Effect of age and caloric restriction on bleomycin-chelatable and nonheme iron in different tissues of C57BL/6 mice.

The objective of this study was to test the hypothesis that the widely observed age-associated increase in the amounts of macromolecular oxidative damage is due to an elevation in the availability of redox-active iron, that is believed to catalyze the scission of H2O2 to generate the highly reactive hydroxyl radical. Concentrations of bleomycin-chelatable iron and nonheme iron were measured in various tissues and different regions of the brain of mice fed on ad libitum (AL) or a calorically restricted (to 60% of AL) diet at different ages. The concentrations of these two pools of iron varied markedly as a function of tissue, age, and caloric intake. There was no consistent ratio between the amounts of nonheme and the bleomycin-chelatable iron pools across these conditions. Nonheme iron concentration increased with age in the liver, kidney, heart, striatum, hippocampus, midbrain and cerebellum of AL animals, whereas bleomycin-chelatable iron increased significantly with age only in the liver. Amounts of both nonheme and bleomycin-chelatable iron remained unaltered during aging in the cerebral cortex and hindbrain of AL mice. Caloric restriction had no effect on iron concentration in the brain or heart, but caused a marked increase in the concentration of both bleomycin-chelatable and nonheme iron in the liver and the kidney. The results do not support the hypothesis that accumulation of oxidative damage with age, or its attenuation by CR, are associated with corresponding variations in redox-active iron.     

Development of smooth and skeletal muscle cells in the iris of the domestic duck,chick and quail

Summary Embryonic development of the avian iris muscle was studied by light and electron microscopy in order to clarify the origin of the iridial skeletal muscle cells. In normal development of the domestic duck, chick, and quail, the muscle bundles appearing in the iris at stage 35 consisted solely of smooth muscle cells. Undifferentiated cells appeared at stage 36, and finally skeletal muscle cells were observed at stage 37. This sequence suggests that stromal mesenchymal cells migrate into the muscle bundles to become skeletal muscle cells.Tissue culture of whole indes removed from duck embryos at stages 30 through 34 produced skeletal muscle cells while culture of isolated iridial epithelia removed at stages 31 and 32 did not. Removal of the midbrain region of duck embryos at stage 10 frequently produced severe disorganization of the eye concomitant with craniofacial deformities typical of a neural crest mesenchymal defect. These severely disorganized eyes were devoid of iridial skeletal muscle cells. These results also suggest mesenchymal origin of iridial skeletal muscle cells.     

Self-association of the Lentivirus protein, Nef

Background

The HIV-1 pathogenic factor, Nef, is a multifunctional protein present in the cytosol and on membranes of infected cells. It has been proposed that a spatial and temporal regulation of the conformation of Nef sequentially matches Nef's multiple functions to the process of virion production. Further, it has been suggested that dimerization is required for multiple Nef activities. A dimerization interface has been proposed based on intermolecular contacts between Nefs within hexagonal Nef/FynSH3 crystals. The proposed dimerization interface consists of the hydrophobic B-helix and flanking salt bridges between R105 and D123. Here, we test whether Nef self-association is mediated by this interface and address the overall significance of oligomerization.

Results

By co-immunoprecipitation assays, we demonstrated that HIV-1Nef exists as monomers and oligomers with about half of the Nef protomers oligomerized. Nef oligomers were found to be present in the cytosol and on membranes. Removal of the myristate did not enhance the oligomerization of soluble Nef. Also, SIVNef oligomerizes despite lacking a dimerization interface functionally homologous to that proposed for HIV-1Nef. Moreover, HIV-1Nef and SIVNef form hetero-oligomers demonstrating the existence of homologous oligomerization interfaces that are distinct from that previously proposed (R105-D123). Intracellular cross-linking by formaldehyde confirmed that SF2Nef dimers are present in intact cells, but surprisingly self-association was dependent on R105, but not D123. SIV_MAC239Nef can be cross-linked at its only cysteine, C55, and SF2Nef is also cross-linked, but at C206 instead of C55, suggesting that Nefs exhibit multiple dimeric structures. ClusPro dimerization analysis of HIV-1Nef homodimers and HIV-1Nef/SIVNef heterodimers identified a new potential dimerization interface, including a dibasic motif at R105-R106 and a six amino acid hydrophobic surface.

Conclusions

We have demonstrated significant levels of intracellular Nef oligomers by immunoprecipitation from cellular extracts. However, our results are contrary to the identification of salt bridges between R105 and D123 as necessary for self-association. Importantly, binding between HIV-1Nef and SIVNef demonstrates evolutionary conservation and therefore significant function(s) for oligomerization. Based on modeling studies of Nef self-association, we propose a new dimerization interface. Finally, our findings support a stochastic model of Nef function with a dispersed intracellular distribution of Nef oligomers.