Andrzej Pastuszyn

Analysis of nutritional components of eight famine foods of the Republic of Niger

In the western Sahel, indigenous plants become important staples when cereal harvests are inadequate to support populations inhabiting that region of Africa. The purpose of this study was to assess the nutrient content of several of these edible wild plants. The leaves of the following seven plant foods were analyzed: Ziziphus mauritiana, Cerathotheca sesamoides, Moringa oleifera, Leptadenia hastata, Hibiscus sabdarifa, Amaranthus viridi, and Adansonia digitata. The fatty acid, vitamin E, carotenoid, selected mineral and amino acid contents of these plant foods were determined. These same analyses were performed on the fruit of the Adansonia digitata. In quantitative and qualitative terms, Amaranthus viridis was found to be an excellent source of protein. Its amino acid composition compared favorably to that of a World Health Organization (WHO) protein standard. It also contained considerable amounts of the two fatty acids that are essential in humans (linoleic and α-linolenic) and a number of minerals including iron, magnesium, calcium and zinc. The leaves of Hibiscus sabdarifa contained an appreciable quantity of protein the composition of which was comparable to the WHO standard. The mineral content of the leaves of this plant was also exceptionally high; noteworthy was its high zinc content. H. sabdarifa also contained significant quantities of the two essential fatty acids. Ziziphus mauritiana was an excellent source of the essential fatty acid linoleic acid and several of the metals including iron, calcium, magnesium and zinc. Its content of other essential nutrients, however, was rather low. In general, Adansonia digitata leaves were nutritionally superior to the fruit of the tree; however, the fruit did contain useful quantities of potassium, phosphorus, zinc and α-linolenic acid. The Leptadenia hastata leaves were an especially good source of lutein and β-carotene. These data should be useful to the people who inhabit the western Sahel in helping them devise healthy diets during times when cereal staples are in short supply.

Nutrient content of the edible leaves of seven wild plants from Niger.

Wild plants play an important role in the diet of the inhabitants of Niger. These plants tend to be drought-resistant and are gathered both in times of plenty as well as times of need. Used in everyday cooking, famine foods may be an important source of nutrients. The goal of this study was to investigate the nutritional role of wild plants in the nigérien diet. To this end, leaves of seven plants species were analyzed for their mineral, amino acid and fatty acid contents: Ximenia americana, Amaranthus viridus, Corchorus tridens, Hibiscus sabdarifa, Maerua crassifolia, Moringa oleifera, and Leptadenia hastata. Ximenia americana} contained large amounts of calcium. Large quantities of iron were present in Amaranthus viridus. All seven plants contained significant amounts of selenium and phosphorus. Corchorus tridens contained the most protein (19–25% dry weight), and its composition compared favorably to the World Health Organizations standard for essential amino acids. Moringa oleifera contained 17% protein and compared favorably with the WHO standard. Corchorus tridens contained the largest amounts of the two essential fatty acids linoleic and α-linolenic acids. These results reinforce the growing awareness that wild edible plants of the Western Sahel can contribute useful amounts of essential nutrients, including amino acids, fatty acids and trace minerals, to human diets.

Elevated protein carbonylation in the brain white matter and gray matter of patients with multiple sclerosis

Oxidative stress has been implicated in the pathophysiology of multiple sclerosis (MS). Increased levels of reactive oxygen species (ROS) derived from infiltrating macrophages and microglial cells have been shown to reduce the levels of endogenous antioxidants and to cause the oxidation of various substrates within the MS plaque. To determine whether oxidative damage takes place beyond visible MS plaques, the occurrence of total carbonyls (TCOs) and protein carbonyls (PCOs) in the normal‐appearing white matter (NAWM) and gray matter (NAGM) of eight MS brains was assessed and compared with those of four control brains. The data show that most (7/8) of the MS‐WM samples contain increased amounts of PCOs as determined by reaction with 2,4‐dinitrophenylhydrazine and Western blot analysis. These samples also have high levels of glial fibrilary acidic protein (GFAP), suggesting that oxidative damage is related to the presence of small lesions. In contrast, we detected no evidence of protein thiolation (glutathionylation and cysteinylation) in the diseased tissue. To our surprise, MS‐NAGM specimens with high GFAP content also showed three times the concentration of TCOs and PCOs as the controls. The increase in PCOs is likely to be a consequence of reduced levels of antioxidants, in that the concentration of nonprotein thiols in both MS‐WM and ‐GM decreased by 30%. Overall, our data support the current view that both NAWM and ‐GM from MS brains contain considerable biochemical alterations. The involvement of GM in MS was also supported by the decrease in the levels of neurofilament light protein in all the specimens analyzed. To the best of our knowledge, this is the first study demonstrating the presence of increased protein carbonylation in post‐mortem WM and GM tissue of MS patients.

Sterol carrier and lipid transfer proteins.

The discovery of the sterol carrier and lipid transfer proteins was largely a result of the findings that cells contained cytosolic factors which were required either for the microsomal synthesis of cholesterol or which could accelerate the transfer or exchange of phospholipids between membrane preparations. There are two sterol carrier proteins present in rat liver cytosol. Sterol carrier protein 1 (SCP1) (Mr 47 000) participates in the microsomal conversion of squalene to lanosterol, and sterol carrier protein 2 (SCP2) (Mr 13 500) participates in the microsomal conversion of lanosterol to cholesterol. In addition SCP2 also markedly stimulates the esterification of cholesterol by rat liver microsomes, as well as the conversion of cholesterol to 7 alpha-hydroxycholesterol - the major regulatory step in bile acid formation. Also, SCP2 is required for the intracellular transfer of cholesterol from adrenal cytoplasmic lipid inclusion droplets to mitochondria for steroid hormone production, as well as cholesterol transfer from the outer to the inner mitochondrial membrane. SCP2 is identical to the non-specific phospholipid exchange protein. While SCP2 is capable of phospholipid exchange between artificial donors/acceptors, e.g. liposomes and microsomes, it does not enhance the release of lipids other than unesterified cholesterol from natural donors/acceptors, e.g. adrenal lipid inclusion droplets, and will not enhance exchange of labeled phosphatidylcholine between lipid droplets and mitochondria. Careful comparison of SCP2 and fatty acid binding protein (FABP) using six different assay procedures demonstrates separate and distinct physiological functions for each protein, with SCP2 participating in reactions involving sterols and FABP participating in reactions involving fatty acid binding and/or transport. Furthermore, there is no overlap in substrate specificities, i.e. FABP does not possess sterol carrier protein activity and SCP2 does not specifically bind or transport fatty acid. The results described in the present review support the concept that intracellular lipid transfer is a highly specific process, far more substrate-specific than suggested by the earlier studies conducted using liposomal techniques.

Sterol Carrier and Lipid Transfer Proteins

Publisher Summary The discovery of the lipid exchange, transfer, or carrier proteins is a result of the findings that cells contained cytosolic factors that were required for microsomal synthesis of cholesterol or could accelerate the transfer or exchange of phospholipids between membrane preparations. Most of the lipid exchange transfer or carrier activities have been characterized as cytosolic factors. These activities might be concentrated in cell particulate fractions, such as microsomes, and might be released to varying extents by tissue homogenization and/or treatment of the “cytosolic” fraction. The phospholipid exchange and transfer activities have been determined by the exchange or transfer of labeled phospholipids between microsomes and mitochondria or liposomes. These more direct assays involving aspects of cholesterol metabolism suggest the possibility that there is greater biological specificity for sterol carrier protein 2 (SCP 2) than is implied by the term non-specific lipid transfer protein. Another protein with apparent biological specificity is fatty acid-binding protein (FABP). Three approaches have been employed to determine fatty acid-binding protein (FABP) activities: Sephadex G-50 chromatography of liver cytosol following addition of [ 14 C] oleate; use of hydrophobic Lipidex 1000 to separate FABP-bound from unbound fatty acids; and immunoprecipitation technique.

Structural determinants influencing the reaction of cysteine-containing peptides with palmitoyl-coenzyme A and other thioesters

Non-enzymatic thioesterification of specific cysteinyl peptides with fatty acyl-CoA has been previously demonstrated in both liposomes and aqueous medium. To identify the molecular basis for the differential reactivity of polypeptides in aqueous solutions, 26 synthetic cysteinyl peptides encompassing the palmitoylation sites of well known proteins (protein zero, proteolipid protein, beta-adrenergic receptor, p21(K-ras), transferrin receptor, CD-4 and SNAP-25) and six small thiol compounds were incubated separately with [3H]palmitoyl-CoA, [14C]acetyl-CoA and p-nitrophenyl thioacetate (NPTA). For each peptide, both the observed reaction rate constant at pH 7.5 and the pH-independent rate constant (k(2)) were calculated, and reactivity of the attacking sulfhydryl group was characterized using the Brønsted equation (log k(2)=beta(nuc) pK(a)+C). In general, peptides bearing basic and aromatic amino acid residues showed the lowest thiol pK(a)s, and consequently displayed the highest acylation rates. Reaction with palmitoyl-CoA was complicated to analyze because of the variable partition of peptides in the acyl chain donor/detergent micelles. In contrast, a linear Brønsted relationship was found for the reaction of the peptides with the water-soluble acetyl-CoA (beta(nuc)=0.59). A similar beta(nuc) value was obtained with the neutral NPTA, indicating that electronic effects other than those responsible for the acid-base properties of the thiol are less important. Thus, the concentration of the thiolate anion appears to be the major factor influencing the rate of the nucleophilic substitution reaction. These findings and the fact that the acylation sites in most proteins are surrounded by basic amino acids may partially explain the specificity of non-enzymatic palmitoylation regarding the acceptor sequences.

Magnetic resonance lipid signals in rat brain after experimental stroke correlate with neutral lipid accumulation.

Proton magnetic resonance spectroscopy (MRS) signals from lipids in brain have been observed to increase after ischemic brain injury. However, neither the chemical identity nor the cellular location of these lipids has been established. The aim of the present study was to identify the origin of MRS lipid signals in rat brain after temporary (90 min) middle cerebral artery occlusion (MCAO). Fatty acyl proton signals were detected by short-echo one and two dimensional (1)H MRS in superfused brain slices from the infarcted hemisphere 1-5 days after MCAO. The intensities of these signals were strongly correlated with the amount of triacylglyceride and cholesterol ester in lipid extracts from the samples (r(2)=0.96, P<0.05) and were not correlated with the amount of free fatty acids in the tissue. Histological staining of tissue revealed the presence of neutral lipid droplets in infarcted regions. Dual labeling by immunohistochemistry demonstrated that these droplets were localized to microglia/macrophage (OX-42-labeled cells). These results strongly suggest that (1)H MRS lipid signals from brain after stroke arise from microglia/macrophage phagocytosis of cellular membranes.

Evidence of Nitrosative Damage in the Brain White Matter of Patients with Multiple Sclerosis

Nitric oxide (NO) has been implicated in the pathophysiology of both experimental autoimmune encephalomyelitis and multiple sclerosis (MS). NO-mediated protein damage in MS appears to be confined to large plaques where 3-nitrotyrosine has been detected. To determine whether nitrosative damage takes place beyond visible MS plaques, the occurrence of various NO-triggered protein modifications in normal-appearing white matter (NAWM) of eight MS brains was assessed and compared to that in white matter (WM) of four control brains. As determined by amino acid analysis and western blotting, no evidence of tyrosine nitration was found in the MS samples studied, suggesting that they did not contain appreciable amounts of plaque-derived material. The amino acid composition of total myelin proteins and proteolipid protein (PLP) was also unaltered in the diseased tissue, as was the fatty acid composition of PLP. In addition, we detected no changes in the number of protein free thiols suggesting that oxidation do not occur to any appreciable extent. However, the levels of nitrite in MS-NAWM were higher than those in control WM, while in the MS-gray matter (GM) the concentration of this ion was unaltered. Furthermore, five of the MS samples analyzed, and the same as those with high levels of glial fibrilary acidic protein, showed increased amounts of protein nitrosothiols as determined by the “biotin switch” method. S-nitrosation of GM proteins was again normal. There was no indication of N-nitrosation of tryptophan and N-terminal amino groups in both control and MS tissue. Overall, the data suggests that WM, but not GM, from MS brains is subjected to considerable nitrosative stress. This is the first report to present direct evidence of increased protein S-nitrosation and nitrite content in the brain parenchyma of MS patients.

Serum and Urinary Amino Acid Levels in Sickle Cell Disease

Neonates with sickle cell disease (SCD) are of normal size at birth in terms of height and weight. However, by the sixth month of life their growth begins to lag significantly behind that of non-sicklers. We hypothesize that such growth retardation could be explained, at least in part, by the increased excretion of free amino acids in the urine of children with SCD. It is well established that in SCD there are abnormalities in the proximal tubules where amino acids are reabsorbed. We collected serum and urine samples from 13 patients with SCD (age range, 10 months to 14 years), and 17 age-and gender-matched controls, and analysed these specimens for free amino acids and creatinine. The SCD population was less well nourished than the controls, as evidenced by the lower serum prealbumin levels in the former group (91.3 v. 127 mg/l, P = 0.01). The serum concentrations of all of the essential amino acids were significantly reduced (21-47 per cent, P < 0.01) in the SCD subjects, as were those of most of the non-essential amino acids (exceptions: alanine, glutamic acid, proline). The urine concentrations of seven of the essential amino acids (indexed to creatinine) were increased in the SCD children. The greatest difference in urinary amino acid excretion was seen with methionine; the SCD subjects excreted 3.6-fold more methionine than the controls. These data indicate that reduced levels of serum amino acids resulting from increased urinary loss of these amino acids in children with SCD could contribute to the decreased growth rates one sees in children with this genetically inherited hematologic disorder.

Identification of the Palmitoylation Site in Rat Myelin P0 Glycoprotein

Abstract: P0 glycoprotein, the major protein of PNS myelin, contains approximately 1 mol of covalently bound long‐chain fatty acids. To determine the chemical nature of the fatty acid‐protein linkage, P0 was labeled in rat sciatic nerve slices with [3H]palmitic acid and subsequently treated with various reagents. The protein‐bound palmi‐tate was released by incubation with the reducing agents dithiothreitol and 2‐mercaptoethanol, and with 1M hydrox‐ylamine at pH 7.5. In addition, P0 was deacylated by treatment with 10 mM NaBH4 with the concomitant production of [3H]hexadecanol, indicating that the fatty acid is bound in a thioester linkage. This conclusion was supported further by the fact that deacylation with hydroxylamine generated free thiol groups, which were titrated with [14C]‐iodoacetamide. To identify the cysteine residue involved in the thioester linkage, [14C]carboxyamidomethylated P0was digested with trypsin and the resulting peptides analyzed by reversed‐phase HPLC. Identification of the radioactive protein fragments by amino acid analysis and amino‐terminal peptide sequencing revealed that Cys153 in rat P0 glycoprotein is the acylation site. The acylated cysteine is located at the junction of the putative transmem‐brane and cytoplasmic domains. This residue is also present in the P0 glycoprotein of other species, including human, bovine, mice, and chicken.