C. Ganesh scite author profile

The folding and stability of maltose binding protein (MBP) have been investigated as a function of pH and temperature by intrinsic tryptophan fluorescence, far- and near-UV circular dichroism, and high-sensitivity differential scanning calorimetric measurements. MBP is a monomeric, two-domain protein containing 370 amino acids. The protein is stable in the pH range of 4-10.5 at 25 degrees C. The protein exhibits reversible, two-state, thermal and guanidine hydrochloride-mediated denaturation at neutral pH. The thermostability of MBP is maximal at pH 6, with a Tm of 64.9 degrees C and a deltaHm of 259.7 kcal mol(-1). The linear dependence of deltaHm on Tm was used to estimate a value of deltaCp of 7.9 kcal mol(-1) K(-1) or 21.3 cal (mol of residue)(-1) K(-1). These values are higher than the corresponding deltaCp's for most globular proteins studied to date. However, the extrapolated values of deltaH and deltaS (per mole of residue) at 110 degrees C are similar to those of other globular proteins. These data have been used to show that the temperature at which a protein undergoes cold denaturation depends primarily on the deltaCp (per mol of residue) and that this temperature increases with an increase in deltaCp. The predicted decrease in stability of MBP at low temperatures was experimentally confirmed by carrying out denaturant-mediated unfolding studies at neutral pH at 2 and 28 degrees C.

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Reversible formation of on‐pathway macroscopic aggregates during the folding of maltose binding protein

Ganesh

Zaidi

Udgaonkar

et al. 2001

Protein Science

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Maltose binding protein (MBP) is widely used as a model for protein folding and export studies. We show here that macroscopic aggregates form transiently during the refolding of MBP at micromolar protein concentrations. Disaggregation occurs spontaneously without any aid, and the refolded material has structure and activity identical to those of the native, nondenatured protein. A considerable fraction of protein undergoing folding partitions into the aggregate phase and can be manually separated from the soluble phase by centrifugation. The separated MBP precipitate can be resolubilized and yields active, refolded protein. This demonstrates that both the soluble and aggregate phases contribute to the final yield of refolded protein. SecB, the cognate Escherichia coli cytosolic chaperone in vivo for MBP, reduces but does not entirely prevent aggregation, whereas GroEL and a variety of other control proteins have no effect. Kinetic studies using a variety of spectroscopic probes show that aggregation occurs through a collapsed intermediate with some secondary structure. The aggregate formed during refolding can convert directly to a near native state without going through the unfolded state. Further, optical and electron microscopic studies indicate that the MBP precipitate is not an amyloid.

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Effect of Crowding Agents, Signal Peptide, and Chaperone SecB on the Folding and Aggregation ofE. coliMaltose Binding Protein

Kulothungan¹,

Das²,

Johnson³

et al. 2009

Langmuir

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SecB, a soluble cytosolic chaperone component of the Sec export pathway, binds to newly synthesized precursor proteins and prevents their premature aggregation and folding and subsequently targets them to the translocation machinery on the membrane. PreMBP, the precursor form of maltose binding protein, has a 26-residue signal sequence attached to the N-terminus of MBP and is a physiological substrate of SecB. We examine the effect of macromolecular crowding and SecB on the stability and refolding of denatured preMBP and MBP. PreMBP was less stable than MBP (DeltaT(m )= 7 +/- 0.5 K) in both crowded and uncrowded solutions. Crowding did not cause any substantial changes in the thermal stability of MBP (DeltaT(m )= 1 +/- 0.4 K) or preMBP (DeltaT(m )= 0 +/- 0.6 K), as observed in spectroscopically monitored thermal unfolding experiments. However, both MBP and preMBP were prone to aggregation while refolding under crowded conditions. In contrast to MBP aggregates, which were amorphous, preMBP aggregates form amyloid fibrils. Under uncrowded conditions, a molar excess of SecB was able to completely prevent aggregation and promote disaggregation of preformed aggregates of MBP. When a complex of the denatured protein and SecB was preformed, SecB could completely prevent aggregation and promote folding of MBP and preMBP even in crowded solution. Thus, in addition to maintaining substrates in an unfolded, export-competent conformation, SecB also suppresses the aggregation of its substrates in the crowded intracellular environment. SecB is also able to promote passive disaggregation of macroscopic aggregates of MBP in the absence of an energy source such as ATP or additional cofactors. These experiments also demonstrate that signal peptide can greatly influence protein stability and aggregation propensity.

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Prediction of the maximal stability temperature of monomeric globular proteins solely from amino acid sequence

Ganesh¹,

Eswar²,

Srivastava³

et al. 1999

FEBS Letters

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Globular protein thermostability is characterized the cold denaturation, maximal stability (T ms ) and heat denaturation temperatures. For mesophilic globular proteins, T ms typically ranges from 3 325³C to +35³C. We show that the indirect estimate of T ms from calorimetry and the direct estimate from chemical denaturation performed in a range of temperatures are in close agreement. The heat capacity change of unfolding per mol residue (v vC p ) alone is shown to accurately predict T ms . v vC p and hence T ms can be predicted solely from the protein sequence. The average difference in free energy of unfolding at the observed and predicted values of T ms is 1.0 kcal mol 31 , which is small compared to typical values of the total free energy of unfolding.z 1999 Federation of European Biochemical Societies.

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Disordered N‐terminal residues affect the folding thermodynamics andkinetics of maltose binding protein

et al. 1999

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Maltose binding protein (MBP) exhibits a slow phase of folding at pH 7.4, 298 K. The kinetics of this phase has been characterized as a function of denaturant concentration and temperature. Denaturant double-jump experiments and the activation energy for folding indicate that the slow phase involves processes other than proline isomerization. Although the first five N-terminal residues are disordered in the MBP crystal structure, mutations in this region slow down folding and destabilize the native structure. This is the first report showing that disordered N-terminal residues can affect folding kinetics and stability.

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C. Ganesh

Thermodynamic Characterization of the Reversible, Two-State Unfolding of Maltose Binding Protein, a Large Two-Domain Protein

Reversible formation of on‐pathway macroscopic aggregates during the folding of maltose binding protein

Effect of Crowding Agents, Signal Peptide, and Chaperone SecB on the Folding and Aggregation ofE. coliMaltose Binding Protein

Prediction of the maximal stability temperature of monomeric globular proteins solely from amino acid sequence

Disordered N‐terminal residues affect the folding thermodynamics andkinetics of maltose binding protein

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