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Compressibility  
  
2650   02:16 صباحاً   date: 25-12-2015
Author : K. Gekko
Book or Source : In Water Relationship in Food
Page and Part :


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Date: 6-12-2015 1659
Date: 23-12-2015 2444
Date: 25-5-2021 1921

Compressibility

 

Compressibility is an important measure of the atomic packing and flexibility of protein molecules. Measurement of this quantity is possible, in principle, only for proteins in solution. The partial specific compressibility of a protein in solution b is defined as the change in the partial specific volume v2 0 with increasing pressure. Since the atomic van der Waals volume, vc, may be assumed to be incompressible, the experimentally determined b of a protein can be mainly attributed to its cavities vcav, and to changes in hydration Dvsol

The first term on the right-hand side contributes positively, and the second term negatively, to b. Thus, a positive b value can be ascribed to a large cavity effect overcoming the hydration effect. There exist two types of compressibilities, depending on the experimental conditions: adiabatic and isothermal. Most compressibility studies of proteins have been of adiabatic compressibility because of its accuracy and technical convenience.

 1. Adiabatic Compressibility

The partial specific adiabatic compressibility bs is calculated with the Laplace equation, bs = 1/u2d, where u is the sound velocity and d the density of the protein solution. The sound velocity is usually measured with an accuracy of 1 cm sec–1 by using a resonance or sing-around pulse method at 3 to 6 MHz. All amino acids show large negative bs, with values between –62.5 × 10–12 cm2 dyn–1 (for glycine) and –21 × 10–12 cm2 dyn–1 (for tryptophan) at 25°C, because they have a negligibly small amount of cavity. Data for bs have been reported for about 40 different proteins; some values in water (or in dilute buffer at neutral pH) are listed in Table 1. Fibrous proteins show negative bs, indicating the dominant effects of the surface on hydration relative to internal cavity volume. On the contrary, most globular proteins have positive bs, due to the large contribution of the internal cavities overcoming the hydration effect. This is consistent with the fact that more than 50% of the total surface area is buried in the interior of a folded protein molecule.

Table 1. Partial specific volume (v20), compressibility (bs and bT), and volume fluctuation (dVrms) of proteins in water at 25°C (1, 4)

a The values in parentheses represent the experimental data; the other values were calculated with Equation 2 of the text.

b The values in parentheses represent the ratio (%) of dVrms to the total protein volume.

Some assumptions are necessary for estimating separately the contributions of cavities and hydration to bs. A rough estimation suggests that the intrinsic compressibility of globular proteins free from hydration is of the order of (10 to 20) × 10–12 cm2 dyn–1. This value is comparable to the adiabatic compressibility of normal ice, suggesting that an internal protein structure is as rigid as ice.

As can be seen in Table 1, the value of bs varies over a wide range and is sensitive to the structural characteristics of individual proteins. For example, lysozyme has a considerably smaller bs than does a-lactalbumin, in spite of their great similarities in primary and tertiary structures. However, the compressibility-structure relationships of proteins have been scarcely discussed on a molecular level, because of the complicated contribution of hydration. The contributions of some structural factors have been deduced by the statistical analyses of bs data on globular proteins (Ref. 1). From the ratio of accessible surface area to volume, bs would be expected to increase with increasing molecular weight, but there appears no definite correlation between bs and molecular weight. Instead, a positive correlation is found between bs and the partial specific volume. Hydrophobic proteins show large positive bs, probably due to an enhanced imperfect packing of nonpolar residues localized in the interior of the molecule. Typical a-helical proteins, such as myoglobin and bovine serum albumin have very large bs, even though the a-helix itself is rigid, predominantly nonhelical proteins, such as trypsin and soybean trypsin inhibitor, have small bs. These results suggest that the a-helix could be a dynamic domain for the thermal fluctuation of proteins. Four amino acids (Leu, Glu, Phe, and His( show statistically a strong ability to increase bs, whereas another four (Asn, Gly, Ser, and Thr( decrease it, although the meaning of this is obscure. A single amino acid substitution can bring about a noticeable change in bs, probably due to modified atomic packing, even though it is rare to observe any visible changes in the tertiary structures of mutants by X-ray crystallography.

Adiabatic compressibility data for nonnative conformations and for unfolding processes, in combination with partial specific volume, also present useful information on the principles of protein structure that cannot be obtained by spectroscopic techniques. Unfolding of a protein with strong denaturants such as guanidinium chloride decreases the compressibility and specific volume, but it is known that the compressibility increases and the partial specific volume decreases on thermal and pressure denaturation.

2. Isothermal Compressibility

 The volume fluctuations and the pressure-dependent properties of proteins are theoretically related to the partial specific isothermal compressibility bT, rather than the adiabatic one bs. To determine bT, the solution density or partial specific volume must be measured as a function of pressure, under hydrostatic pressure or centrifugal force. Such an experiment is very difficult, however, and few bT data are available for proteins, because high pressure may cause protein denaturation and modify preferential solvent interactions. Approximate values of bT may be estimated from bs by utilizing the relationship 

if the thermal expansion coefficient a and the heat capacity at constant pressure Cp, are known or can be reasonably inferred. Such assumed bT values are listed in Table 1, along with some experimental data. Despite many assumptions, the calculated values of bT are not so very different from the experimentally observed ones. The value of bT is greater than bs by (3 to 4) × 10-12 cm2 dyn–1; these differences are comparable to those found for the amino acids.

 There are some other methods to evaluate the isothermal compressibility of proteins, although the value obtained is not a partial quantity in solution. Kundrot and Richard (2) reported 4.7 × 1012 cm2 dyn–1 for bT of lysozyme by comparing its X-ray crystallographic volume at atmospheric pressure and 1000 atmospheres. Contraction of the molecule was distributed nonuniformly; one domain was essentially incompressible, but another had a large compressibility. Computer simulations, such as molecular dynamics, Monte Carlo, and normal mode analyses, are also available. Normal mode analysis of myoglobin yielded bT = 9.37 × 10–12 cm2 dyn–1.

According to statistical thermodynamics, the volume fluctuation dVp of a protein with volume Vp is related to its isothermal compressibility bT (Ref. 3):

where k is the Boltzmann constant and T the absolute temperature. The root-mean-square fluctuation of the partial molar volume dVrms, which was estimated by using bT instead of bT, is listed in the last column of Table 1. The volume fluctuation is only about 0.3% of the overall dimensions of protein, but the dVrms values estimated by this method are the lower limit of the probable fluctuations, since the solvation factor is still included in the value of bT that was used. If the intrinsic isothermal compressibility of a protein itself, which is not easy to determine, is used instead of bT, a greater volume fluctuation (up to 50% greater) might be expected for a protein without hydration. Although many assumptions are used in estimating bT and the fluctuation of volume, the values obtained are considered to be reasonable; if concentrated in one area at one particular moment, the fluctuation in volume could produce sufficient cavities or channels to allow the entry of solvent or probe molecules to account for phenomena such as hydrogen exchange and fluorescence quenching observed with folded proteins.

References

1. K. Gekko and Y. Hasegawa (1986) Biochemistry 25, 6563–6571

2. E. Kundrot and F. M. Richards (1987) J. Mol. Biol. 193, 157–170

3. A. Cooper (1976) Proc. Natl. Acad. Sci. U.S.A. 73, 2740–2741

4. K. Gekko (1991) In Water Relationship in Food (H. Levine and L. Slade, eds.), Plenum Press, New York, pp. 753–771. 




علم الأحياء المجهرية هو العلم الذي يختص بدراسة الأحياء الدقيقة من حيث الحجم والتي لا يمكن مشاهدتها بالعين المجرَّدة. اذ يتعامل مع الأشكال المجهرية من حيث طرق تكاثرها، ووظائف أجزائها ومكوناتها المختلفة، دورها في الطبيعة، والعلاقة المفيدة أو الضارة مع الكائنات الحية - ومنها الإنسان بشكل خاص - كما يدرس استعمالات هذه الكائنات في الصناعة والعلم. وتنقسم هذه الكائنات الدقيقة إلى: بكتيريا وفيروسات وفطريات وطفيليات.



يقوم علم الأحياء الجزيئي بدراسة الأحياء على المستوى الجزيئي، لذلك فهو يتداخل مع كلا من علم الأحياء والكيمياء وبشكل خاص مع علم الكيمياء الحيوية وعلم الوراثة في عدة مناطق وتخصصات. يهتم علم الاحياء الجزيئي بدراسة مختلف العلاقات المتبادلة بين كافة الأنظمة الخلوية وبخاصة العلاقات بين الدنا (DNA) والرنا (RNA) وعملية تصنيع البروتينات إضافة إلى آليات تنظيم هذه العملية وكافة العمليات الحيوية.



علم الوراثة هو أحد فروع علوم الحياة الحديثة الذي يبحث في أسباب التشابه والاختلاف في صفات الأجيال المتعاقبة من الأفراد التي ترتبط فيما بينها بصلة عضوية معينة كما يبحث فيما يؤدي اليه تلك الأسباب من نتائج مع إعطاء تفسير للمسببات ونتائجها. وعلى هذا الأساس فإن دراسة هذا العلم تتطلب الماماً واسعاً وقاعدة راسخة عميقة في شتى مجالات علوم الحياة كعلم الخلية وعلم الهيأة وعلم الأجنة وعلم البيئة والتصنيف والزراعة والطب وعلم البكتريا.