Effect of Dephosphorylation on the Self-association and the Precipitation of β-Casein

The pyrolyzate of the nondialyzable melanoidin prepared from glucose-ammonia reaction system (kept in pH 5.3~6.0 during the reaction) was fractionated to volatile fraction and nonvolatile fraction. Among the volatile components, two pyridines and four alkylpyrazines were identified. On the other hand, one imidazole compound and two β-hydroxypyridines isolated from the nonvolatile fraction were identified as 4(5)-methylimidazole, 3-hydroxypyridine and 2-methyl-5-hydroxypyridine, respectively. It is inferred that these compounds are not produced by the fission of the main skeleton in the melanoidin molecule, but formed by pyrolysis of the heterocyclic compounds present as a small moiety in the melanoidin.     

Implication of C-Terminal Deletion on the Structure and Stability of Bovine β-casein

Bovine β-casein (β-CN) with its C-terminal truncated by chymosin digestion, β-CN-(f1-192), was examined and characterized using circular dichroism (CD) under various temperature conditions. CONTIN/LL analysis of the CD data revealed significant secondary structure disruption in β-CN-(f1-192) relative to its parent protein,β-CN, in the temperature range (5° to 70°C) studied. Near-UV CD spectra indicated significant temperature dependent structural changes. Analytical ultracentrifugation results showed significant reduction but not complete abolishment of self-association in β-CN-(f1-192) compared to whole β-casein at 2°–37°C. Furthermore, binding experiments with the common hydrophobic probe – 8-anilino-1- naphthalene sulfonic acid (ANS) illustrated that β-CN-(f1-192) is nearly incapable of binding to ANS relative to whole β-CN, suggesting a nearly complete open overall tertiary structure brought about by the C-terminal truncation. It has been demonstrated clearly that the tail peptide β-CN-(f193-209) is important in maintaining the hydrophobic core of β-CN but the residual association observed argues for a minor role for other sites as well.     

Folding up and Moving on—Nascent Protein Folding on the Ribosome

All cellular proteins are synthesized by the ribosome, an intricate molecular machine that translates the information of protein coding genes into the amino acid alphabet. The linear polypeptides synthesized by the ribosome must generally fold into specific three-dimensional structures to become biologically active. Folding has long been recognized to begin before synthesis is complete. Recently, biochemical and biophysical studies have shed light onto how the ribosome shapes the folding pathways of nascent proteins. Here, we discuss recent progress that is beginning to define the role of the ribosome in the folding of newly synthesized polypeptides.     

The Formation of Casein Micelles Reconstituted with Ca<Superscript>+2</Superscript> and Added Inorganic Phosphate is Influenced by the Non-phosphorylated Form of Human β-Casein

The β-casein (CN) human milk fraction is comprised of a single protein phosphorylated at levels from 0 to 5. Component interactions are dependent on the phosphorylation level. Here, 3 mg/ml of β-CN-0P, β-CN-2P, β-CN-4P, a 2P/4P 1:1 (wt:wt) mixture, or a mixture of all six forms in the ratio in human milk, were mixed with bovine κ-CN at a κ/β molar ratio of 0.33. Measurements were with 0, 5 and 10 mM Ca⁺² and 4 and 8 mM added inorganic phosphate (P_i). The turbidity (OD_{400 nm}) and a lack of precipitation as T increased from 4 to 37°C was an index of micelle formation. The results indicate: (1) while micelles will form with Ca⁺² alone, added P_i has a significant enhancing effect on micelle formation; (2) the patterns of micelle formation as a function of T are influenced by the β-CN-0P and β-CN-1P forms of β-CN to an unexpected extent.     

Effect of Methylglyoxal Modification of Human α-Crystallin on the Structure,Stability and Chaperone Function

α-Crystallin functions as a molecular chaperone and maintains transparency of eye lens by protecting other lens-proteins. Non-enzymatic glycation of α-crystallin by methylglyoxal, plays a crucial role on its chaperone function and structural stability. Our studies showed that methylglyoxal modification even in lower concentration caused significant decrease in chaperone function of α-crystallin as reflected both in thermal aggregation assay and enzyme refolding assay. Thermal denaturation studies showed drastic reduction of denaturation temperature with increase in the degree of modification. Thermodynamic stability studies by urea denaturation assay reflected a decrease of transition midpoint. Quantitatively we found that ΔG° of native α-crystallin decreased from 21.6 kJ/mol to 10.4 kJ/mol due to 72 h modification by 10 mM methylglyoxal. The surface hydrophobicity of α-crystallin after MG modification, was found to be decreased. Circular dichroism spectroscopy revealed conversion of β-sheet structure to random coil structure. Significant cross-linking was also observed due to methylglyoxal modification of human α-crystallin.     

Effects of Turn Stability and Side-Chain Hydrophobicity on the Folding of β-Structures

Key elements of β-structure folding include hydrophobic core collapse, turn formation, and assembly of backbone hydrogen bonds. In the present folding simulations of several β-hairpins and β-sheets (peptide 1, protein G B1 domain peptide, TRPZIP2, TRPZIP4, 20mer, and 20mer^DP6D), the folding free-energy landscape as a function of several reaction coordinates corresponding to the three key elements indicates apparent dependence on turn stability and side-chain hydrophobicity, which demonstrates different folding mechanisms of similar β-structures of varied sequences. Turn stability is found to be the key factor in determining the formation order of the three structural elements in the folding of β-structures. Moreover, turn stability and side-chain hydrophobicity both affect the stability of backbone hydrogen bonds. The three-stranded β-sheets fold through a three-state transition in which the formation of one hairpin always takes precedence over the other. The different stabilities of two anti-parallel hairpins in each three-stranded β-sheet are shown to correlate well with the different levels of their hydrophobic interactions.     

The Effect of pH and Heat Pre-Treatments on the Physicochemical and Emulsifying Properties of β-lactoglobulin

The overall goal of this research was to investigate structure-function mechanisms associated the emulsifying properties β-lactoglobulin (β-LG). Specifically the physicochemical (i.e., surface charge and hydrophobicity, size and interfacial tension) and emulsifying (i.e., emulsification activity (EAI) and stability indices (ESI)) properties of β-LG were investigated in response to changes in pH (3.0, 5.0 and 7.0) and heat pre-treatment conditions (25, 55 and 85 °C). Hydrophobicity was found to be greatest at pH 5.0/85 °C, whereas at all conditions it was significantly lower. Surface charge on β-LG was found to be neutral at?~?pH 3.9, regardless of conditions. Aggregate size was also found to be highest at pH 5.0/85 °C (avg. hydrodynamic radii of ~714 nm), corresponding to a reduced net surface charge and high hydrophobicity. Little size dependence of aggregates was observed at pH 3.0 regardless to the temperature pre-treatments (radii ~120 nm). In contrast, at pH 7.0 slight temperature dependence was apparent, where treatments at 25, 55 and 85 °C led to radii of 412.8, 307.2 and 232.3 nm, respectively. Overall, the addition of β-LG to a canola oil–water system resulted in a decline in interfacial tension from ~28 mN/m to ~18 mN/m, however the effect of pH/temperature conditions was minimal. EAI was found to be highest when β-LG solutions displayed high surface charge combined with moderate hydrophobicity. In contrast, ESI was higher under conditions where β-LG solutions remained in a native (25 °C) or fully denatured state (85 °C) versus one in where partially unravelling may be occurring (55 °C).     

The Characterization of Rennin Action on κ-Casein Using CM-Cellulose

Rennin action on κ-Casein was studied using the CM-cellulose method which determines the amount of para-κ-casein formed during the enzymatic hydrolysis of κ-casein. The reaction rate was measured as a function of the time and enzyme concentration. A Km value of 8.9 ×10^?4m and a V value of 1.2 × 10^?4 M/min were obtained under the assay condition used in this study. The maximum initial rate of para-κ-casein formation occurred at pH 5.0 and 50°C. The present study also demonstrated that the CM-cellulose method is useful for measuring the rennin activity on κ-casein.     

Effect of Inducers on the Production of 5‐Aminolevulinic Acid by Recombinant Escherichia coli

Abstract

Aminolevulinic acid (ALA) was produced by recombinant Escherichia coli BL21(DE3) (pET28‐A.R‐hemA) harboring the ALA synthase gene (hemA) from Agrobacterium radiobacter zju‐0121. The effects of inducers on the ALA synthase activity and ALA productivity were evaluated. The results indicated that a low isopropyl‐β‐D‐thiogalactoside (IPTG) concentration (0.05 mmol/L) was favorable for high expression of ALA synthase, which resulted in higher ALA productivity. For metabolic engineering applications, lactose was a better substitute of IPTG for active enzyme expression. When lactose concentration was 5 mmol/L, the specific ALA synthase activity and ALA productivity reached 16.7 nmol/(min · mg of protein) and 1.15 g/L, respectively, which were about 15% and 43% higher than those induced by IPTG.     

Effect of the Disease-Causing R266K Mutation on the Heme and PLP Environments of Human Cystathionine β-Synthase

Cystathionine β-synthase (CBS) is an essential pyridoxal 5'-phosphate (PLP)-dependent enzyme of the transsulfuration pathway that condenses serine with homocysteine to form cystathionine; intriguingly, human CBS also contains a heme b cofactor of unknown function. Herein we describe the enzymatic and spectroscopic properties of a disease-associated R266K hCBS variant, which has an altered hydrogen-bonding environment. The R266K hCBS contains a low-spin, six-coordinate Fe(III) heme bearing a His/Cys ligation motif, like that of WT hCBS; however, there is a geometric distortion that exists at the R266K heme. Using rR spectroscopy, we show that the Fe(III)-Cys(thiolate) bond is longer and weaker in R266K, as evidenced by an 8 cm(-1) downshift in the ν(Fe-S) resonance. Presence of this longer and weaker Fe(III)-Cys(thiolate) bond is correlated with alteration of the fluorescence spectrum of the active PLP ketoenamine tautomer. Activity data demonstrate that, relative to WT, the R266K variant is more impaired in the alternative cysteine-synthesis reaction than in the canonical cystathionine-synthesis reaction. This diminished cysteine synthesis activity and a greater sensitivity to exogenous PLP correlate with the change in PLP environment. Fe-S(Cys) bond weakening causes a nearly 300-fold increase in the rate of ligand switching upon reduction of the R266K heme. Combined, these data demonstrate cross talk between the heme and PLP active sites, consistent with previous proposals, revealing that alteration of the Arg(266)-Cys(52) interaction affects PLP-dependent activity and dramatically destabilizes the ferrous thiolate-ligated heme complex, underscoring the importance of this hydrogen-bonding residue pair.     

The Expression of Nerve Growth Factor Receptor on Schwann Cells and the Effect of These Cells on Regeneration of Axons in Traumatically Injured Human Spinal Cord

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The Effect of TGF-β1 on Expression of Chemokine and Its Receptor in Human Decidual Stromal Cells

为探讨转化生长因子β1(TGF-β1)在蜕膜基质细胞中发挥免疫调节作用的机制,本研究以人妊娠初期的蜕膜基质细胞为研究对象,经0 ng/ml、1 ng/ml、5 ng/ml和10 ng/ml的TGF-β1处理后,运用RT-PCR方法检测趋化因子mRNA的表达,Western-blot检测趋化因子蛋白质的表达.结果表明:在mRNA水平和蛋白水平,高浓度的TGF-β1能够显著的下调蜕膜基质细胞中趋化因子配体CX3CL1、CXCL12和CXCL16的表达,有意义的上调趋化因子受体CXCR4和CXCR6的表达.研究结果提示,TGF-β1对趋化因子配体/受体有显著的调节作用,并通过趋化因子参与母胎界面的免疫调节.     

The Combined Effect of Glucose and β-Hydroxybutyrate on the Membrane Potential of Synaptosomal Mitochondria

Biophysics - Abstract—The ketogenic diet is used as a treatment for different brain diseases. It involves replacement of dietary carbohydrates with fat, which leads to production of ketone...     

The Combined Effect of Shungite and Heavy Metals on the Growth of Microalgae Роpulation

The combined effect of 3 mg/L potassium dichromate, 1.5 mg/L cadmium sulfate, and 100 g/L shungite on the growth of chlorococcales green microalgae culture Scenedesmus quadricauda (Turp.) Bréb. is studied. The toxic effect of potassium dichromate and cadmium sulfate on S. quadricauda is estimated by calculating the share of living and dead cells and physiological parameters. The toxic effect of heavy metals does not manifest itself under the combined action of potassium dichromate or cadmium sulfate and shungite on S. quadricauda. The best growth of the algae culture occurred only when only shungite was added to the culture medium. Shungite can be used to neutralize the toxic effect of heavy metals.     

Effect of Recombinant Interferon-α2b (Laferon) on Transport of Sodium Ions in Human Neuroblastoma Cells

To elucidate molecular mechanisms of neurotropic action of a recombinant interferon, IFN-2b (laferon), its effect on transport of ²²Na⁺ through the membrane of cultured human neuroblastoma cells (line IMR 32) was investigated. Within the first minutes after treatment with IFN-2b, the influx of ²²Na⁺ ions was reduced by 20%, as compared with the control. Depolarization of the plasma membrane by a mixture of veratrine and scorpion (Leiurus quinquestriatus) toxin (200 and 10 g/ml, respectively) increased this flux by 50% in the control and by 70% in the IFN-2b-treated cells. A blocker of voltage-operated sodium channels, tetrodotoxin (TTX, 4 · 10^-7 M), suppressed the inward flux of ²²Na⁺ ions (completely in the control cells and by 75% in the IFN-2b-treated cells). The influx of ²²Na⁺ ions into neuroblastoma cells depended on the concentration of IFN-2b in the incubation medium, reaching a maximum at concentrations of 600-1000 IU/ml. This allows us to suggest that entry of Na⁺ ions into neuroblastoma cells caused by IFN-2b is basically performed through voltage-operated TTX-sensitive sodium channels.     

Structural Aspects and Chaperone Activity of Human HspB3: Role of the “C-Terminal Extension”

HspB3, an as yet uncharacterized sHsp, is present in muscle, brain, heart, and in fetal tissues. A point mutation correlates with the development of axonal motor neuropathy. We purified recombinant human HspB3. Circular dichroism studies indicate that it exhibits β-sheet structure. Gel filtration and sedimentation velocity experiments show that HspB3 exhibits polydisperse populations with predominantly trimeric species. HspB3 exhibits molecular chaperone-like activity in preventing the heat-induced aggregation of alcohol dehydrogenase (ADH). It exhibits moderate chaperone-like activity towards heat-induced aggregation of citrate synthase. However, it does not prevent the DTT-induced aggregation of insulin, indicating that it exhibits target protein-dependent molecular chaperone-like activity. Unlike other sHsps, it has a very short C-terminal extension. Fusion of the C-terminal extension of αB-crystallin results in altered tertiary and quaternary structure, and increase in polydispersity of the chimeric protein, HspB3αB-CT. The chimeric protein shows comparable chaperone-like activity towards heat-induced aggregation of ADH and citrate synthase. However, it shows enhanced activity towards DTT-induced aggregation of insulin. Our study, for the first time, provides the structural and chaperone functional characterization of HspB3 and also sheds light on the role of the C-terminal extension of sHsps.     

The Occurrence of Matriptase C-Terminal Fragments on the Apical and Basolateral Sides of Madin–Darby Canine Kidney Epithelial Cells

Matriptase is a type II transmembrane serine protease. In the present study, matriptase C-terminal fragments containing the catalytic serine protease domain were found to occur on the apical and basolateral sides of Madin–Darby canine kidney epithelial cells transfected with a cDNA encoding the protease. This suggests that matriptase interacts with various potential substrates when expressed in simple epithelia.     

Effect of Quinoline-Type Antimalarial Drugs on the Binding of Oestradiol-17β and Progesterone by Rabbit and Human Uterine Cytosols

Abstract

Rabbit and human uterine cytosol, prepared and tested in phosphate buffer, bound less oestradiol-17β or progesterone than cytosol from the same source prepared and tested in Tris-HCl buffer. Dissociation constants were the same in both buffer systems, and the difference in binding was due to a difference in the number of binding sites. Three quinoline-type antimalarial drugs, chloroquine, quinine and mefloquine, and the quinoline derivative, 4-(4'-hydroxy-l'-methylbutylamino)-7-chloroquinoline, increased the steroid binding capacity of phosphate-buffered cytosol to that of Tris-buffered cytosol, the optimal concentration of quinoline derivative being 1.4–1.6 mM. Tris (50 mM) increased the binding capacity of phosphate-buffered cytosol to that of Tris-buffered cytosol. The effects of Tris and quinoline derivatives were not additive. By gel chromatography and sucrose density gradient centrifugation it was shown that the molecular size and sedimentation behaviour of the oestradiol and progesterone receptors were not affected by the quinoline derivatives. Two types of binding site are proposed, one requiring the presence of low molecular weight, basic compounds. The uterine levels of chloroquine attained by normal pharmacological doses of the drug are potentially capable of influencing the binding of oestradiol-17β and progesterone in the uterine cytosol.     

Effect of Chlorpromazine on the Binding of Oestradiol-17β by Human Uterine Cytosol

Abstract

Chlorpromazine increases the binding of oestradiol-17β by human uterine cytosol in vitro. This effect is due to an increase in the number of receptor sites, and the dissociation constant for oestradiol-17β is unaffected by chlorpromazine.     

Preparation and Properties of Recombinant Rat and Human Procholecystokinin57 –95

Recombinant human progastrin_6–80 binds two ferric ions with an apparent dissociation constant of 2.2 ± 0.1 μM [Baldwin (2004) Protein J 23:65–70]. The aims of the present study were to express fragments of recombinant procholecystokinin and to determine whether or not they bound ferric ions. Recombinant rat and human procholecystokinin_57–95 were expressed as glutathione S-transferase fusion proteins in E. coli. The fusion proteins were bound to glutathione-agarose, cleaved with thrombin, and purified by reverse phase HPLC. Recombinant procholecystokinin_57–95 did not bind to either the CCK1 or CCK2 receptor with high affinity. No change in absorption spectrum was observed on addition of ferric ions, and analysis of the quenching of tryptophan fluorescence observed in the presence of ferric ions indicated that binding to procholecystokinin_57–95 was at least 40–fold weaker than the binding of ferric ions to progastrin_6–80.