Effects of fat, protein, and carbohydrate and protein load on appetite, plasma cholecystokinin, peptide YY, and ghrelin, and energy intake in lean and obese men

While protein is regarded as the most satiating macronutrient, many studies have employed test meals that had very high and unsustainable protein contents. Furthermore, the comparative responses between lean and obese subjects and the relationships between energy intake suppression and gut hormone release remain unclear. We evaluated the acute effects of meals with modest variations in 1) fat, protein, and carbohydrate content and 2) protein load on gastrointestinal hormones, appetite, and subsequent energy intake in lean and obese subjects. Sixteen lean and sixteen obese men were studied on four occasions. Following a standardized breakfast, they received for lunch: 1) high-fat (HF), 2) high-protein (HP), 3) high-carbohydrate/low-protein (HC/LP), or 4) adequate-protein (AP) isocaloric test meals. Hunger, fullness, and gut hormones were measured throughout, and at t = 180 min energy intake at a buffet meal was quantified. In lean subjects, hunger was less and fullness greater following HF, HP, and AP compared with HC/LP meals, and energy intake was less following HF and HP compared with HC meals (P < 0.05). In the obese subjects, hunger was less following HP compared with HF, HC/LP, and AP meals, and energy intake was less following HP and AP compared with HF and HC meals (P < 0.05). There were no major differences in hormone responses to the meals among subject groups, but the CCK and ghrelin responses to HP and AP were sustained in both groups. In conclusion, HP meals suppress energy intake in lean and obese subjects, an effect potentially mediated by CCK and ghrelin, while obese individuals appear to be less sensitive to the satiating effects of fat.     

Mesenchymal Stem/Stromal Cells under Stress Increase Osteosarcoma Migration and Apoptosis Resistance via Extracellular Vesicle Mediated Communication

Studies have shown that mesenchymal stem/stromal cells (MSCs) from bone marrow are involved in the growth and metastasis of solid tumors but the mechanism remains unclear in osteosarcoma (OS). Previous studies have raised the possibility that OS cells may receive support from associated MSCs in the nutrient deprived core of the tumors through the release of supportive macromolecules and growth factors either in vesicular or non-vesicular forms. In the present study, we used stressed mesenchymal stem cells (SD-MSCs), control MSCs and OS cells to examine the hypothesis that tumor-associated MSCs in nutrient deprived core provide pro-proliferative, anti-apoptotic, and metastatic support to nearby tumor cells. Assays to study of the effects of SD-MSC conditioned media revealed that OS cells maintained proliferation when compared to OS cells grown under serum-starved conditions alone. Furthermore, OS cells in MSCs and SD-MSC conditioned media were significantly resistant to apoptosis and an increased wound healing rate was observed in cells exposed to either conditioned media or EVs from MSCs and SD-MSCs. RT-PCR assays of OS cells incubated with extracellular vesicles (EVs) from SD-MSCs revealed microRNAs that could potentially target metabolism and metastasis associated genes as predicted by in silico algorithms, including monocarboxylate transporters, bone morphogenic receptor type 2, fibroblast growth factor 7, matrix metalloproteinase-1, and focal adhesion kinase-1. Changes in the expression levels of focal adhesion kinase, STK11 were confirmed by quantitative PCR assays. Together, these data indicate a tumor supportive role of MSCs in osteosarcoma growth that is strongly associated with the miRNA content of the EVs released from MSCs under conditions that mimic the nutrient deprived core of solid tumors.     

Rotary bioreactor culture can discern specific behavior phenotypes in Trk-null and Trk-expressing neuroblastoma cell lines

Neuroblastoma is characterized by biological and genetic heterogeneity that leads to diverse, often unpredictable, clinical behavior. Differential expression of the Trk family of neurotrophin receptors strongly correlates with clinical behavior; TrkA expression is associated with favorable outcome, whereas TrkB with unfavorable outcome. Neuroblastoma cells cultured in a microgravity rotary bioreactor spontaneously aggregate into tumor-like structures, called organoids. We wanted to determine if the clinical heterogeneity of TrkA- or TrkB-expressing neuroblastomas was reflected in aggregation kinetics and organoid morphology. Trk-null SY5Y cells were stably transfected to express either TrkA or TrkB. Short-term aggregation kinetics were determined by counting the number of single (non-aggregated) viable cells in the supernatant over time. Organoids were harvested after 8 d of bioreactor culture, stained, and analyzed morphometrically. SY5Y-TrkA cells aggregated significantly slower than SY5Y and SY5Y-TrkB cells, as quantified by several measures of aggregation. SY5Y and TrkB cell lines formed irregularly shaped organoids, featuring stellate projections. In contrast, TrkA cells formed smooth (non-stellate) organoids. SY5Y organoids were slightly smaller on average, but had significantly larger average perimeter than TrkA or TrkB organoids. TrkA expression alone is sufficient to dramatically alter the behavior of neuroblastoma cells in three-dimensional, in vitro rotary bioreactor culture. This pattern is consistent with both clinical behavior and in vivo tumorigenicity, in that SY5Y-TrkA represents a more differentiated, less aggressive phenotype. The microgravity bioreactor is a useful in vitro tool to rapidly investigate the biological characteristics of neuroblastoma and potentially to assess the effect of cytotoxic as well as biologically targeted drugs.     

Profilin oligomerization and its effect on poly (l-proline) binding and phosphorylation

Profilin is a cytoskeletal protein that interacts specifically with actin, phosphoinositides and poly (l-proline). Experimental results and in silico studies revealed that profilin exists as dimer and tetramer. Profilin oligomers possess weak affinity to poly (l-proline) due to unavailability of binding sites in dimers and tetramers. Phosphorylation studies indicate that profilin dimers are not phosphorylated while teramers are preferentially phosphorylated over monomers. In silico studies revealed that PKC phosphorylation site, S137 is buried in dimer while it is accessible in tetramer.     

Production of dimethyl triselenide and dimethyl diselenenyl sulfide in the headspace of metalloid-resistant Bacillus species grown in the presence of selenium oxyanions

A Bacillus species harvested from the environment is metalloid resistant and, when grown anaerobically in complex growth medium and amended with the selenium oxyanion selenate, selenite, or selenocyanate, produces volatile organoselenium compounds in bacterial culture headspace. Two novel compounds so far undetected in bacterial culture headspace, CH₃Se₂SCH₃ and CH₃SeSeSeCH₃, are produced and can be detected using solid-phase microextraction and gas chromatography with either fluorine-induced chemiluminescence or mass spectrometric detection. Differences in the electron impact fragmentation pattern of the mixed sulfur/selenide compounds allow the tentative differentiation between the symmetric and asymmetric isomers in this bacterium’s headspace in favor of the asymmetric CH₃SeSeSCH₃ isomer.     

Simple,Fast, and Sensitive Method for Quantification of Tellurite in Culture Media

A fast, simple, and reliable chemical method for tellurite quantification is described. The procedure is based on the NaBH₄-mediated reduction of TeO₃²⁻ followed by the spectrophotometric determination of elemental tellurium in solution. The method is highly reproducible, is stable at different pH values, and exhibits linearity over a broad range of tellurite concentrations.The tellurium oxyanion tellurite is toxic for most organisms, making important its accurate assessment. Several methods for quantifying tellurite have been described to date. However, most of them are rather complicated and require sophisticated equipment and in some cases the detection is not quite sensitive enough to allow the assessment of TeO₃²⁻ concentrations below 50 μg/ml (200 μM). For example, the analytical determination of tellurium (Te) oxyanions by atomic absorption spectrometry (AAS) is hampered by poor sensitivity. Where flame or electrothermal AAS routinely yields detection limits of less than 10 ppb for iron (16), normal flame AAS tellurium detection limits are 100 to 1,000 times higher and require pretreatment to achieve the +IV oxidation state before analysis (11).On the other hand, hydride generation AAS (HGAAS) is used to achieve ppb-level detection limits for Se and Te as well as arsenic and antimony among others. For Te the volatile hydride gas H₂Te is generated by first converting the metalloid to the +IV oxidation state and then by chemical reduction to the gaseous hydride using—almost universally—sodium borohydride (NaBH₄). In automated HGAAS systems, an inert purge gas sweeps the volatile hydride formed in a glass reaction vessel into a quartz cell heated by the AAS flame where gaseous hydride decomposition and atomization occur. Though tellurite reduction, precipitation, and detection methods have been reported (3, 17), they are temporally relatively unstable and pH dependent.Since tellurium is toxic and environmentally important (7, 8), determining low concentrations in bacterial cultures is very desirable and a simple analysis without pretreatment steps that could quickly establish total metalloid oxyanion content in a liquid sample would be a plus. Here we report a new method for the determination of tellurite in bacterial culture media. This procedure is based on the NaBH₄ reduction of tellurite to the elemental form, which is analyzed spectrophotometrically at 500 nm or 320 nm (see below), by which the light scattered by the particles of elemental metalloid in solution is measured. While the detection limits do not compare to those of HGAAS (14) or capillary electrophoresis (13), they do approach those of old flame AAS but involve a much simpler and quicker procedure requiring only one reagent and a spectrophotometer to determine total content of solutions of +IV oxyanions in solution. Linear calibration range, method development time and probe stability, effect of sample pH, common interferences, and detection limits were investigated.Calibration curves to determine K₂TeO₃ concentrations in routinely used microbiological culture media such as Luria-Bertani (LB) or M9 minimal medium amended with 0.2% glucose (15) were constructed. A set of solutions containing increasing concentrations of K₂TeO₃ (Sigma) were prepared in LB or M9 culture medium, and the tellurium oxyanion was quantitatively reduced using freshly prepared 3.5 mM NaBH₄ (final concentration).The reaction was carried out at 60°C for 10 min (bubbling was overcome by vortexing), and after 5 min at room temperature, the optical density at 500 nm (OD₅₀₀) was determined spectrophotometrically as described previously (4, 5, 9, 12). Blanks contained no borohydride. Figure ​Figure11 shows that in both media good curve linearity was obtained, with r² values of 0.9740 and 0.9963 for LB and M9, respectively. Tellurite concentrations lower than 1 μg/ml or higher than 200 μg/ml were also tested, but OD₅₀₀ values were close to the spectrophotometer error limit at low concentrations or nonlinear above 200 μg/ml (not shown). Thus, the NaBH₄ method allows determination of a wide range of tellurite concentrations in a fast and simple way. Tellurite concentrations lower than 50 μg/ml in both rich and minimal media can be easily determined; the experimental error was about 10%, similar to that reported for the diethyl dithiocarbamate (DDTC) tellurite method (17).Open in a separate windowFIG. 1.Calibration curves to determine K₂TeO₃ concentrations in LB (A) (R² = 0.9963) or M9 minimal (B) (R² = 0.9740) medium. Optical density at 500 nm was determined after reducing the oxyanion with sodium borohydride. Error bars denote 1 standard deviation of three replicates.To analyze the resulting solutions after tellurite reduction by NaBH₄, absorption/scattering spectra were determined. Figure ​Figure22 shows that spectra from LB and those from M9 after tellurite reduction are quite different, which may be a consequence of the different chemical compositions of these culture media. In both cases, absorption spectra showed linearity between optical density at 500 nm and tellurite concentration in the sample. However, high tellurite concentrations (∼100 μg/ml) caused a loss of linearity in LB medium.Open in a separate windowFIG. 2.Absorption spectra after reducing samples of LB (A) or M9 (B) culture medium containing increasing tellurite concentrations with 3.5 mM NaBH₄. Tellurite concentrations used were 20, 40, 60, 80, and 100 (LB) and 2, 4, 6, 8, and 10 (M9) μg/ml. (Inset) Calibration curve in M9 medium using the absorbance maxima at 320 nm.Figure ​Figure2B2B shows that in M9 medium there is a zone around 320 nm exhibiting higher optical density than that at 500 nm, which represents an advantage in the determination of tellurite in chemically defined culture media. This is reflected in a wider range of measurable concentrations at 320 nm (Fig. ​(Fig.2B,2B, inset), as well as in a higher sensitivity of the method as determined by the slope of the calibration curve. The product of tellurite reduction by NaBH₄ showed good stability at both wavelengths in rich and minimal culture media (not shown).Since in M9 medium the method allows the determination of minor tellurite concentrations (1 to 20 μg/ml), it would be of great help in assessing tellurite uptake in tellurite-sensitive microorganisms whose MICs range from 1 to 10 μg/ml. Sulfur-containing salts, commonly present in culture media as sulfites and sulfates, did not interfere with our NaBH₄ method for tellurite assessment at concentrations up to 0.5 M (not shown).As shown in Fig. ​Fig.3,3, tellurite assessment was not affected by the pH of the culture medium. In fact, linearity was observed in a wide pH range with minor slope changes in LB. Similar results were obtained with M9 medium, although tellurite assessment was not possible at pH values higher than 7.0 because of the formation of a precipitate. This may be due to an interaction of the phosphate salts present in the medium and some charged (2⁺) chemical species forming at alkaline pH values, as has been reported earlier (17).Open in a separate windowFIG. 3.Effect of pH in determining tellurite concentrations in LB (A) and M9 minimal (B) media.To date, the most commonly used procedure for determining tellurite in culture media is that involving the spectrophotometric determination (340 nm) of the complex that forms between tellurite and diethyl dithiocarbamate (17). This procedure has been used to assess tellurite uptake by the phototrophic bacterium Rhodobacter capsulatus, which is naturally resistant to K₂TeO₃ (MIC, ∼1.4 mM) (2, 3). However, K₂TeO₃ uptake studies in highly sensitive cells such as Escherichia coli (MIC, ∼4 μM) are difficult to carry out because of the low concentrations of toxicant present in the culture medium, far below the detection limit of the DDTC procedure (17).In this context and for testing the applicability of our method in vivo, we used the tellurite-sensitive bacterium E. coli BW25113 (10) and the tellurite-resistant Aeromonas caviae ST (5, 6). An overnight culture of E. coli BW25113 in M9 minimal medium was diluted 100-fold with fresh M9 supplemented with 0.2% glucose and grown at 37°C with shaking. When the OD₆₀₀ was 0.1, the culture was amended with 20 μg/ml K₂TeO₃ (arrow, Fig. ​Fig.4A).4A). Then aliquots were taken at the indicated times and cells were centrifuged at 8,500 × g for 3 min; supernatants were used to assess extracellular tellurite by our NaBH₄ method. While added tellurite did not affect bacterial growth (Fig. ​(Fig.4A),4A), the remaining tellurite in the supernatant dropped approximately to one-third after 3 h (Fig. ​(Fig.4B).4B). Tellurite determinations were validated using, in parallel, the DDTC method (not shown).Open in a separate windowFIG. 4.Tellurite uptake by Escherichia coli. Time zero in panel B represents the moment of tellurite addition.Regarding the tellurite-resistant bacterium A. caviae ST, a 1:100 dilution of an overnight culture was inoculated into fresh LB medium and the OD₆₀₀ was recorded at the indicated times. When the OD₆₀₀ was ∼0.4, the culture was amended with tellurite (400 μg/ml final concentration) (Fig. ​(Fig.5A,5A, arrow) and the remaining tellurite in the supernatants was assessed as described above. Figure ​Figure5B5B shows that in 4 h ∼27% of the toxic oxyanion was removed from the culture medium.Open in a separate windowFIG. 5.Tellurite uptake by Aeromonas caviae ST. See the text for details.In summary and in comparison to the DDTC procedure, the NaBH₄ method described here allows more sensitive determination of the initial tellurite concentrations as well as the continuous uptake of the toxicant by tellurite-sensitive and tellurite-resistant microorganisms. This method should be of great help in future studies aimed at unveiling the tellurite reductase activity exhibited by some metabolic enzymes such as nitrate reductase (1), catalase (4), and the pyruvate dehydrogenase complex (5, 6). These studies are currently being carried out in our laboratory.     

Inhibitory effect of cinnamoyl compounds against human malignant cell line

In the present study, anti-proliferative effects of dietary polyphenolic compounds have been observed and demonstrated the strong anticancer efficacy of curcumin (CMN), an active constituent of dietary spice (turmeric) using human leukemia cancer cell line. CMN inhibited the proliferation of K562 leukemic cells by induction of apoptosis. The current study demonstrated synergy with combination of drug therapy, and suggested that combination of ferulic acid and cisplatin synergistically inhibited cellular proliferation. Cytotoxic synergy was observed independent of the sequence of addition of two drugs to cultured cells. The synergized growth inhibitory effect with cisplatin was probably associated with G2-M arrest in cell cycle progression. These findings suggested that among the cinnamoyl compounds, CMN was most potent and FER appeared to be a better modulating agent on human malignant cell line.     

Sterculia guttata seeds extractives--an effective mosquito larvicide

The larvicidal activity of ethanol, chloroform and hexane soxhlet extracts obtained from S. guttata seeds was investigated against the IVth instar larvae of Dengue fever vector, Aedes aegypti and filarial vector, Culex quinquefasciatus. All extracts including fractions of ethanol extract exhibited 100% larval kill within 24 hr exposure period at 500 ppm concentration. Fraction A1 of ethanol was found to be most promising; its LC50 was 21.552 and 35.520 ppm against C. quinquefasciatus and A. aegypti respectively. Naturally occurring S. guttata seed derived fractions merit further study as potential mosquito larval control agents or lead compounds.     

Preparation and characterization of biopolymeric nanoparticles used in drug delivery

Nanotechnology plays an important role in advanced biology and medicine research particularly in the development of potential site-specific delivery systems with lower drug toxicity and greater efficiency. These include microcapsules, liposomes, polymeric microspheres, microemulsions, polymer micelles, hydrogels, solid nanoparticles etc. In the present study, preparation and characterization of biopolymeric gelatin nanoparticles for encapsulating the antimicrobial drug sulfadiazine and its in vivo drug release in phosphate buffer saline (PBS) have been investigated. The nanoparticles prepared by second desolvation process varied in a size range 200 nm and 600 nm with a drug entrapment efficiency of 50% characterized by atomic force microscopy and dynamic light scattering. The drug release from the nanoparticles occurred up to 30% in a controlled manner.