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Critical residues in the folding of beta-lactamaseCraig, S. January 1986 (has links)
No description available.
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Continuous ethanol production in a two-stage, immobilized and suspended cell bioreactorGil, Gwang-Han 08 1900 (has links)
No description available.
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The threshold of cavitation as a function of temperature and frequency for benzene and ethyl alcoholConnolly, Walter Curtis, January 1954 (has links)
Thesis--Catholic University of America. / Bibliography: p. 19.
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Narrowing the molecular weight distribution of linear alcohol ethoxylatesKuo, Betsy P. 05 1900 (has links)
No description available.
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The vapor phase equilibrium in the esterification of ethyl alcohol by acetic acidBrundage, Donald Keith, Halford, Joseph Olney, January 1942 (has links)
From D. K. Brundage's thesis - University of Michigan. / An article, by J. O. Halford and Donald Brundage, reprinted from the Journal of the American Chemical Society, 64, 1942.
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Photon correlation spectroscopy studies of mutual diffusion in aqueous t-butyl alcoholEuliss, Gary W. January 2011 (has links)
Typescript (photocopy). / Digitized by Kansas Correctional Industries
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A dairy-based beverage development by alpha-lactalbumin/beta-lactoglobulin ratio adjustment for dysphagia patientsWei, Ting January 1900 (has links)
Master of Science / Department of Food Science / Karen A. Schmidt / People who suffer from swallowing disorders are diagnosed with dyphasgia. The beverage for the dyphagia patients should have the apparent viscosity in the range of nectar-like (51 to 350 mPa•s) or honey-like (351 to 1750 mPa•s). Due to the swallowing problems, dysphagia patients usually consume beverages slowly. Thus, the apparent viscosity of beverage for such patients should be high enough to be in the suitable range during the entire time of consumption.
Three ratios of α-lactalbumin (α-la)/β-lactoglobulin (β-lg) (3:8, 1:1 and 8:3) were used to prepare the milk systems. These ratio adjusted milk systems were either processed at 70, 80, and 90ºC for 30 min or at 25ºC, and cooled to 25 ± 1ºC. After the process was completed, the milk systems were set quiescently 120 min at 25 ±1ºC. Physical and chemical properties were assessed at various time. For the milk systems at 0 min, the apparent viscosity increased in all 90°C processed-samples, and the increase was in the order of 8:3 (15.96%), 1:1 (6.38%) and 3:8 (2.11%) compared with the 25ºC samples at each ratio. When the milk systems set for 120 min, apparent viscosity increased slightly by 3.7%.
The maximum apparent viscosity was 2.18 mPa•s, which was less than nectar-like. Therefore, xanthan gum was added at 0.15 w/w % to enhance rheological properties of the milk systems. α-La/β-lg ratio adjusted milk systems either with or without xanthan gum were prepared, and processed at 90ºC or 25ºC, and cooled to 25 ± 1ºC. Apparent viscosity increased by 48.61 and 89.61% in 3:8 and 8:3 milk systems, respectively for those at 0.15% xanthan gum concentration and processed at 90ºC compared with at 25ºC. Apparent viscosity of 8:3 milk systems at xanthan gum concentration of 0.15% processed at 90°C was 58.7 ± 2.12 mPa•s which was within the nectar-like range. When the samples were set for 120 min, no changes were found in the apparent viscosity of the milk systems. If the rheological properties of the milk systems can be controlled by ingredients interactions, this can be used to develop nutritious products with different forms for dysphagia patients.
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A Study of the Interactions Between Milk Proteins and Soy ProteinsNarayanaswamy, Venkatachalam 01 May 1997 (has links)
This research investigates the protein interactions that occur when soy protein is added to milk and subjected to renneting or heating. Milk was fortified with 20% soy protein and enzymic coagulation studied at 35°C at various pH's and CaCl2 levels. The first part deals with the interaction between milk and soy proteins during rennet-induced milk coagulation. The first goal was to determine how soy proteins affected milk coagulation. The effects of native versus heat-denatured soy proteins on rennet coagulation time and curd firmness were compared. lmmunogold labeling along with transmission electron microscopy was used to identify and localfze soy proteins in coagulated milk. Partitioning of ß-conglycinin and glycinin, the two main soy protein fractions, between cheese and whey was determined by electrophoresis.
Soy proteins affected milk coagulation to the greatest extent at pH 6.6. Both heat-denatured and native soy proteins increased rennet coagulation time. Only heat-denatured soy proteins affected final curd firmness. Most of ß-conglycinin was lost in whey, whereas glycinin was retained in curd.
Soy proteins existed in the curd as aggregates that were less electron dense than casein micelles. At pH 6.6, heat-denatured soy proteins were fibrous and adhered to the surfaces of casein micelle, preventing direct micelle-micelle contact. This would delay aggregation rate and decrease curd firmness by decreasing the number and strength of links between casein micelles. Native soy proteins did not bind to the casein micelles but rather were physically trapped within curd. Their effect of delaying aggregation is thought to be a function of their binding of calcium. Adding CaCl2 or lowering the pH to 6.3 or 6.0 helped restore coagulation properties.
The second goal was to determine what heat-induced interaction occurs between milk and soy proteins, specifically between κ-casein and glycinin. Both κ-casein and glycinin are heat labile and form insoluble aggregates when heated. When glycinin and κ-casein were heated together, some acidic polypeptides of glycinin crosslinked with κ-casein via disulfide linkages. However, when disulfide linkage was prevented by adding ß-mercaptoethanol , non-covalent interactions between κ-casein and both acidic and basic polypeptides of glycinin occurred that prevented the heat precipitation of glycinin. This non-covalent interaction between glycinin polypeptides and κ-casein may explain why the heat-treated soy proteins became attached to the surfaces of casein micelles during rennet coagulation of milk.
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UNDERSTANDING FORCES THAT CONTRIBUTE TO PROTEIN STABILITY: APPLICATION FOR INCREASING PROTEIN STABILITYFu, Hailong 2009 May 1900 (has links)
The aim of this study is to further our understanding of the forces that contribute
to protein stability and to investigate how site-directed mutagenesis might be used for
increasing protein stability. Eleven proteins ranging from 36 to 370 residues have been
studied here. A 36-residue VHP and a 337-residue VlsE were used as model systems for
studying the contribution of the hydrophobic effect on protein stability. Mutations were
made in both proteins which replaced bulky hydrophobic side chains with smaller ones.
All variants were less stable than their wild-type proteins. For VHP, the destabilizing
effects of mutations were smaller when compared with similar mutations reported in the
literature. For VlsE, a similarity was observed. This different behavior was investigated
and reconciled by the difference in hydrophobicity and cavity modeling for both
proteins. Therefore, the stabilizing mechanism of the hydrophobic effect appears to be
similar for both proteins.
Eight proteins were used as model systems for studying the effects of mutating
non-proline and non-glycine residues to statistically favored proline and glycine residues
in ?-turns. The results suggest that proline mutations generally increase protein stability, provided that the replaced residues are solvent exposed. The glycine mutations,
however, only have a stabilizing effect when the wild-type residues have ?, ? angles in
the L? region of Ramachandran plot. Nevertheless, this strategy still proves to be a
simple and efficient way for increasing protein stability.
Finally, using a combination of eight previously identified stabilizing mutations;
we successfully designed two RNase Sa variants (7S, 8S) that have both much higher
Tms and conformational stabilities than wild-type protein over the entire pH range
studied. Further studies of the heat capacity change upon unfolding (?Cps) for both
proteins and their variants suggest that residual structure may exist in the denatured state
of the 8S variant. An analysis of stability curves for both variants suggests that they
achieve their stabilization through different mechanisms, partly attributed to the different
role of their denatured states. The 7S variants may have a more rigid denatured state and
the 8S variant may have a compact denatured state in comparison with that of wild-type
RNase Sa.
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The folding kinetics of ribonuclease Sa and a charge-reversal variantTrefethen, Jared M. 17 February 2005 (has links)
The primary objective was to study the kinetics of folding of RNase Sa. Wild-type
RNase Sa does not contain tryptophan. A tryptophan was substituted at residue
81 (WT*) to allow fluorescence spectroscopy to be used to monitor folding. This
tryptophan mutation did not change the stability. An analysis of the folding
kinetics of RNase Sa showed two folding phases, indicating the presence of an
intermediate and consistent with the following mechanism: D ↔ I ↔ N. Both
refolding limbs of the chevron plot (abcissa = final conc. of denaturant and
ordinate = kinetic rate) had non-zero slopes suggesting that proline
isomerization was not rate-limiting.
The conformational stability of a charge-reversed variant, WT*(D17R), of
a surface exposed residue on RNase Sa has been studied by equilibrium
techniques. This mutant with a single amino acid charge reversal of a surface
exposed residue resulted in decreased stability. Calculations using Coulombs
Law suggested that favorable electrostatic interactions in the denatured state
were the cause for the decreased stability for the charge-reversed variant.
Folding and unfolding kinetic studies were designed and conducted to study the
charge-reversal effect. Unfolding kinetics showed a 10-fold increase in the
unfolding rate constant for WT*(D17R) over WT* and no difference in the rate of
refolding.
Kinetics experiments were also conducted at pH 3 where protonation of
Asp17 (charge reversal site) would be expected to negate the observed kinetic
effect. At pH 3 the kinetics of unfolding of WT* RNase Sa and the WT*(D17R)
mutant were more similar. These kinetic results indicate that a single-site
charge reversal lowered the free energy of the denatured state as suspected.
Additionally, the results showed that the transition state was stabilized as well.
These results show that a specific Coulombic interaction lowered the free energy
in the denatured and transition state of the charge-reversal mutant, more than in
WT*. To our knowledge, this is the first demonstration that a favorable
electrostatic interaction in the denatured state ensemble has been shown to
influence the unfolding kinetics of a protein.
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