黄素氧还蛋白参与的固氮链电子传递

棕色固氮菌中电子载体Fld直接向固氮酶铁蛋白传递电子。Fld_(ox)至Fld_R是双电子二步还原反应,极谱半波电位分别为-210、-550 mV。Fld_(ox)至Fld_(SR)的中点电位为-280 mV,Fld_(SR)至Fld_R为-500mV。铁蛋白中点电位为-256mV,加MgATP后为-390 mV。Fld_R与铁蛋白ox组成的电池电动势为244mV,电子传递可自发进行,反应的J△G~o为-23KJ/摩尔,铁蛋白被Fld_R还原的K_a=1.3×120~4,加入MgATP后△G~o为-10.6KJ/摩尔,K_a=72。因此,未加入MgATP时电子传递反应更易进行。     

Nitrate reductase is not accumulated in chloroplast-ribosome-deficient mutants of higher plants

The activities of nitrite reductase (EC 1.7.7.1) are 60–70% of wild-type activity in pigment-deficient leaves of the chloroplast-ribosomedeficient mutants albostrians (Hordeum vulgare) and iojap (Zea mays). The activity and apoprotein of nitrate reductase (EC 1.6.6.1.) are lacking in the barley mutant. Only very low activities of nitrate reductase can be extracted from leaves of the maize mutant. The molybdenum cofactor of nitrate reductase and xanthine dehydrogenase (EC 1.2.3.2) is present in maize and barley mutant plants. However, it is not inducible by nitrate in pigment-deficient leaves of albostrians. From these results we conclude: (i) Nitrite reductase (a chloroplast enzyme) is synthesized in the cytoplasm and does not need the presence of nitrate reductase for the induction and maintenance if its activity. (ii) The loss or low activity of nitrate reductase is a consequence of the inability of the mutants to accumulate the apoprotein of this enzyme. (iii) The chloroplasts influence the accumulation (i.e. most probably the synthesis) of the nonchloroplast enzyme, nitrate reductase. The accumulation of nitrate reductase needs a chloroplast factor which is not provided by mutant plastids blocked at an early stage of their development.Abbreviations CRM cross-reacting material - Mo-co molybdenum cofactor - NiR nitrite reductase - NR nitrate reductase     

Nicotiana tabacum mutants with chloroplast encoded streptomycin resistance and pigment deficiency

Summary Callus ofNicotiana tabacum SRI, a mutant with maternally inherited streptomycin resistance, was induced from leaf sections. Callus pieces were mutagenised with N-ethyl-N-nitrosourea and inoculated onto a shoot-induction medium on which calli are normally green. White callus sectors were observed in the mutagenised cultures, and white and variegated shoots were regenerated from these sectored calli. The SR1-A10 line regenerated a chimeric shoot with white leaf margins. The chimeric shoot was grafted onto a normal green rootstock, grown into a flowering plant in the greenhouse, and crosses were made. The SRI-A15 line was crossed using flowers formed on albino plants grown in sterile culture. Pigment deficiency was maternally inherited in both lines. Physical mapping of the chloroplast genome of the SR1-A15 mutant by SalI, PstI and BamHI restriction endonucleases did not reveal any difference between the SR1-A15 and the parental SRI chloroplast genomes.     

Dietary selenium status and plasma thyroid hormones in chicks

Experiments were conducted to study the effect of marginal levels of selenium and vitamin E on plasma thyroid hormones of meattype chicks. Plasma thyroxine (T₄) was significantly increased when a semipurified diet was supplemented with either selenium or vitamin E. Triiodothyronine (T₃) was also significantly increased by vitamin E and in one experiment with selenium supplementation. No significant increase in these hormones was observed in birds fed a corn-soybean-meal diet supplemented with these nutrients. Plasma corticosterone level was reduced and weight of the bursa of Fabricius increased by selenium or vitamin E supplementation. These nutrients may be necessary for providing the optimum thyroid conditions for activity of thyroid peroxidase.     

Chlorophyll-protein and polypeptide composition of Mn-deficient sugar beet thylakoids

The chlorophyll-protein and polypeptide composition of manganese deficient and control sugar beet thylakoids was examined using three different detergent-electrophoresis systems. On a per chlorophyll basis, manganese deficiency reduced the amounts of CPa complex (separated by sodium dodecylsulfate (SDS)-polyacrylamide gel electrophoresis), and CP 47 and CP 43 complexes (separated by octylglucoside/SDS-polyacrylamide gel electrophoresis) without decreasing the amounts of light harvesting complexes. Lithium dodecylsulfate/Triton X-100 polyacrylamide gel electrophoresis showed that manganese deficiency decreased several thylakoid polypeptides, including a chlorophyll b containing 30 kilodalton chlorophyll-protein complex, but did not decrease the amounts of 28 and 29 kilodalton light-harvesting chlorophyll b-containing polypeptides.     

Cultural and genetic adaptations to malaria: Problems of comparison

The concept of adaptation has been used differently in studies of biological and cultural evolution, and this divergence raises the question of whether genetic and cultural adaptations are truly comparable. This paper compares genetic and cultural traits associated with endemic malaria in Sardinia, Italy. Thalassemia and G-6-Pd deficiency, two genetic traits of the Island's population, are believed to enhance fitness against malaria, despite increased risk for the diseases of thalassemia major and favism. Two cultural traits, a pastoral pattern of inverse transhumance and rules limiting the geographical mobility of lowland women, limited exposure to the malaria vector, Anopheles labranchiae; these are used as examples of cultural adaptations. The distribution, costs, and benefits of the adaptive cultural and genetic traits are compared, and the theoretical difficulties of finding a common measure of adaptive value are discussed.     

Proton magnetic resonance studies of 7 Fe ferredoxins: Lower potential of the [4 Fe–4 S] redox center than the [3 Fe–3 S] cluster

Two types of iron-sulfur clusters, [3 Fe–3 S] and [4 Fe–4 S], were identified by ¹H-NMR in ferredoxins from Thermus thermophilus, Mycobacterium smegmatis and Pseudomonas ovalis. The [4 Fe–4 S] clusters always showed the redox couples which had potentials lower than that of the [3 Fe–3 S] clusters.     

Differential effects of protein malnutrition and ascorbic acid deficiency on histidine metabolism in the brains of infant nonhuman primates

Abstract: Male infant nonhuman primates (M. nemes-trina) born in captivity were used in the study. They were divided into three groups. The first group of three animals was fed a 20% casein diet and the second group of six monkeys received a 2.0% casein diet. The third group of four monkeys received a 20% casein diet totally devoid of ascorbic acid for 3.5 weeks before the diet was supplemented with ascorbic acid (20 mg/kg diet). All the diets were given to the animals in two daily rations of 100 g/animal. The monkeys fed a 2% casein diet failed to grow, and after about 3.5 months showed variable degrees of edema, hypoalbuminemia, evidence of psychomotor disturbance, depressed plasma levels of many essential amino acids, and other features consistent with the diagnosis of protein-energy malnutrition. Examination of the brains revealed significant alterations in the levels of histidine (+ 172%) and homocarnosine (+ 146%) in comparison with the control well-fed monkeys. Associated with the increase in brain histidine was a marked elevation of brain histamine level. Protein deficiency also led to poor brain retention of ascorbic acid but not to the same degree observed in the ascorbic acid-deficient animals. The latter group of animals, after receiving their diet for about 8 months, demonstrated a modest elevation in the plasma levels of most amino acids in comparison with controls. Ascorbic acid deficiency elicited a significant reduction (p < 0.01) in brain level of histidine, with hardly any change in homocarnosine level. In addition, vitamin C deficiency produced elevation of brain histamine level comparable to findings in the protein-energy-deficient monkeys. The results suggested that protein deficiency raised brain histamine level mainly through increased availability of the precursor amino acid histidine, while defective degradation might account for the increased brain level of this amine in ascorbic acid-deficient monkeys. Histamine has been proposed to have a predominantly depressant action on relevant neurons, and has also been shown to participate with other neuro-transmitters in influencing the function of the pituitary gland by regulating release of the hypothalamic hormones into the portal vessels. The relevance of the findings of marked increases in brain histamine in experimental protein and ascorbic acid deficiencies to the behavioral and extensive endocrinological alterations seen in human malnutrition deserves some intensive investigation.     

Effect of Pyrithiamine Treatment and Subsequent Thiamine Rehabilitation on Regional Cerebral Amino Acids and Thiamine-Dependent Enzymes

Pyrithiamine-induced thiamine-deficiency encephalopathy in the rat shows many neuropathological and biochemical similarities to Wernicke's encephalopathy in humans. Treatment of rats with pyrithiamine resulted in moderate reductions of glutamate in thalamus and pons and in generalized severe reductions of aspartate in pons (by 89%, p less than 0.01), thalamus (by 83%, p less than 0.01), cerebellum (by 53%, p less than 0.01), and cerebral cortex (by 33%, p less than 0.05). Alanine concentrations were concomitantly increased. Activities of the thiamine-dependent enzyme alpha-ketoglutarate dehydrogenase (alpha KGDH) were decreased in parallel with the aspartate decreases; pyruvate dehydrogenase complex activities were unchanged in all brain regions. Following thiamine administration to symptomatic pyrithiamine-treated rats, neurological symptoms were reversed and concentrations of glutamate, aspartate, and alanine, as well as alpha KGDH activities, were restored to normal in cerebral cortex and pons. Aspartate levels and alpha KGDH activities remained below normal values, however, in thalamus. Thus, pyrithiamine treatment leads to reductions of cerebral alpha KGDH and (1) decreased glucose (pyruvate) oxidation resulting in accumulation of alanine and (2) decreased brain content of glutamate and aspartate. Such changes may be of key significance in the pathophysiology of the reversible and irreversible signs of Wernicke's encephalopathy in humans.     

Regionally selective alterations in enzymatic activities and metabolic fluxes during thiamin deficiency

To further elucidate the molecular basis of the selective damage to various brain regions by thiamin deficiency, changes in enzymatic activities were compared to carbohydrate flux through various pathways from vulnerable (mammillary bodies and inferior colliculi) and nonvulnerable (cochlear nuclei) regions after 11 or 14 days of pyrithiamin-induced thiamin deficiency. After 11 days,large decreases (–43 to –59%) in transketolase (TK) occurred in all 3 regions; 2-ketoglutarate dehydrogenase (KGDHC) declined (–45%), but only in mammillary bodies; pyruvate dehydrogenase (PDHC) was unaffected. By day 14, TK remained reduced by 58%–66%; KGDHC was now reduced in all regions (–48 to –55%); PDHC was also reduced (–32%), but only in the mammillary bodies. Thus, the enzyme changes did not parallel the pathological vulnerability of these regions to thiamin deficiency.¹⁴CO₂ production from¹⁴C-glucose labeled in various positions was utilized to assess metabolic flux. After 14 days, CO₂ production in the vulnerable regions declined severely (–46 to 70%) and approximately twice as much as those in the cochlear nucleus. Also by day 14, the ratio of enzymatic activity to metabolic flux increased as much as 56% in the vulnerable regions, but decreased 18 to 30% in the cochlear nuclei. These differences reflect a greater decrease in flux than enzyme activities in the two vulnerable regions. Thus, selective cellular responses to thiamin deficiency can be demonstrated ex vivo, and these changes can be directly related to alterations in metabolic flux. Since they cannot be related to enzymatic alterations in the three regions, factors other than decreases in the activity of these TPP-dependent enzymes must underlie selective vulnerability in this model of thiamin deficiency.Abbreviations KGDHC 2-ketoglutarate dehydrogenase complex EC 1.2.4.2., EC 2.3.1.61, EC 1.6.4.3. - PDHC pyruvate dehydrogenase complex EC 1.2.4.2., EC 2.3.1.12, EC 1.6.4.3 - TK transketolase (EC 2.2.1.1) - TPP thiamin pyrophosphate