Diffusive motions control the folding and unfolding kinetics of the apomyoglobin pH 4 molten globule intermediate.

The sperm whale apomyoglobin pH 4 folding intermediate exists in two forms, Ia and Ib, that mimic transient kinetic intermediates in the folding of the native protein at pH 6. To characterize the nature of the kinetic barrier that controls the formation of the earliest intermediate Ia, we have investigated the effects of small viscogenic cosolvents on its folding and unfolding kinetics. The kinetics are measurable by stopped-flow fluorescence and follow a cooperative two-state model in the absence and presence of cosolvents. Small cosolvents stabilize Ia, but, by applying the isostability test to separate the viscogenic effect of the cosolvent from its stabilizing effect, we found that, in both folding and unfolding conditions, the apparent rate constant decreases when solvent viscosity increases. The unitary inverse dependence of the apparent rate constant on solvent viscosity indicates a diffusion-controlled reaction. This result is consistent with the hypothesis that folding of the apomyoglobin pH 4 intermediate obeys a diffusion-collision model. Additionally, the temperature dependence of the reaction rate at constant viscosity indicates that the formation of Ia is also controlled by an energy barrier. Linear free energy relationships show that the transition state of the U <==> Ia reaction is compact and buries 45% of the surface area that is buried in native apomyoglobin. We conclude that the transition state of the U <==> Ia reaction resembles that for the formation of native proteins; namely, it is dry and its compactness is closer to that of the folded (Ia) form than of the unfolded form.

Development of autologous cytotoxic CD4+ T clones in a human model of B-cell non-Hodgkin follicular lymphoma.

Immunotherapy for cancer aims to generate cytotoxic cells that are capable of eradicating tumour cells. It has been well demonstrated that helper, non-cytotoxic CD4(+) T cells are important for the induction and maintenance of anti-tumour immunity exerted by cytotoxic CD8(+) T cells. In contrast, the existence of direct anti-tumour, effector cytotoxic CD4(+) T cells remains elusive, mainly due to the paucity of reliable experimental data, especially in human B-cell non-Hodgkin lymphomas. This study developed an appropriate, autologous follicular B-cell non-Hodgkin follicular lymphoma model, including the in vitro establishment of a malignant, human leucocyte antigen class I (HLA-I) deficient B-cell line, and the generation of three autologous anti-tumour cytotoxic CD4(+) T-cell clones originating from the peripheral blood of the same patient. These three clones were considered as tumour specific, because they were capable of killing the malignant, HLA-I-deficient B-cell line through a classical HLA-II restricted perforin-mediated pathway, but did not lyse the Epstein-Barr virus-infected autologous normal B lymphocytes. All three CD4(+)clones were T-cell receptor Vbeta17-Dbeta1-Jbeta1.2 and exhibited an identical complementarity-determining region 3, suggesting the immunodominance of a single peptide antigen presented by tumour cells. Such lymphoma models would provide a useful tool for in vivo expansion and the adoptive transfer of selected CD4(+) cytotoxic cells in immunotherapeutic strategies.

Cooperative sub-millisecond folding kinetics of apomyoglobin pH 4 intermediate.

For small single-domain proteins, formation of the native conformation (N) from a fully unfolded form (U) or from a partially folded intermediate (I) occurs typically in a highly cooperative process that can be described by a two-state model. However, it is not clear whether cooperativity arises early along the folding reaction and whether folding intermediates are also formed in highly cooperative processes. Here, we show that each previously identified step leading apomyoglobin from its unfolded form to its native form, namely, the U <= => Ia, the Ia <= => Ib, and the Ib <= => N reactions, exhibits typical features of a two-state reaction. First, refolding and unfolding kinetics of the earliest U <= => Ia reaction are measurable at pH 4.2 within the urea-induced unfolding transition [Jamin, M., and Baldwin, R. L. (1996) Nat. Struct. Biol. 3, 613-618; Jamin, M., and Baldwin, R. L. (1998) J. Mol. Biol. 276, 491-504], and we report here that sub-millisecond kinetics measured by far-UV circular dichroism (CD), a probe of secondary structure, are similar to those measured by Trp fluorescence, a probe of hydrophobic core formation and chain collapse. These results confirm that folding of the earliest intermediate, Ia, occurs in a highly cooperative process, in which hydrophobic collapse and secondary structure formation occur concomitantly in the A(B)GH core. Second, when the refolding of N is measured at high pH, starting from the acid-unfolded ensemble, the formation of Ia occurs in the mixing time of the sub-millisecond stopped-flow, but the subsequent steps, the Ia <= => Ib and Ib <= => N reactions, exhibit similar kinetics by far-UV CD and Trp fluorescence, indicating that these two late stages of the apoMb folding process also occur in highly cooperative, two-state reactions.