Erythema annulare centrifugum in a case of chronic myeloid leukemia.

Chronic myeloid leukemia (CML), BCR-ABL1-positive, is classified as a myeloproliferative neoplasm predominantly composed of proliferating granulocytes and determined to have the Philadelphia chromosome/translocation t (9;22)(q34;q11.2). Skin is said to be the mirror to systemic diseases, with skin manifestations ranging from nonspecific cutaneous lesions to specific lesions. The cutaneous manifestations of CML are generally reddish-brown to violaceous papules and nodules, indurated or hemorrhagic plaques, perifollicular acneiform papules, bullae, and palpable purpura. Other unusual manifestations could be erythema nodosum, pyoderma gangrenosum, erythema annulare centrifugum, and so on. Here we present a case of a 50-year-old woman with a history of recurrent pruritic skin lesions and erythema annulare centrifugum as the presenting complaint of CML.

Guanidine-HCl dependent structural unfolding of M-crystallin: fluctuating native state like topologies and intermolecular association.

Numerous experimental techniques and computational studies, proposed in recent times, have revolutionized the understanding of protein-folding paradigm. The complete understanding of protein folding and intermediates are of medical relevance, as the aggregation of misfolding proteins underlies various diseases, including some neurodegenerative disorders. Here, we describe the unfolding of M-crystallin, a ßγ-crystallin homologue protein from archaea, from its native state to its denatured state using multidimensional NMR and other biophysical techniques. The protein, which was earlier characterized to be a predominantly ß-sheet protein in its native state, shows different structural propensities (α and ß), under different denaturing conditions. In 2 M GdmCl, the protein starts showing two distinct sets of peaks, with one arising from a partially unfolded state and the other from a completely folded state. The native secondary structural elements start disappearing as the denaturant concentration approaches 4 M. Subsequently, the protein is completely unfolded when the denaturant concentration is 6 M. The (15)N relaxation data (T(1)/T(2)), heteronuclear (1)H-(15)N Overhauser effects (nOes), NOESY data, and other biophysical data taken together indicate that the protein shows a consistent, gradual change in its structural and motional preferences with increasing GdmCl concentration.

Temperature-dependent oligomerization in M-crystallin: lead or lag toward cataract, an NMR perspective.

The oligomerization and/or aggregation of proteins is of critical importance in a wide variety of biomedical situations, ranging from abnormal disease states like Alzheimer's and Parkinson's disease to the production of inclusion bodies, stability, and delivery of protein drugs. In the case of eye-lens proteins, oligomerization is implicated in cataract formation. In the present study, we have investigated the temperature driven oligomerization of M-crystallin, a close homologue of eye-lens proteins, using NMR spectroscopy and dynamic-light scattering (DLS). The NMR data primarily included R(1), R(2) relaxation rates and nOes of the backbone amide groups recorded at three different temperatures, 25, 20, and 15° C. The major outcome of the study is the two fold increase in the overall tumbling time (τ(c)) of M-crystallin on lowering the temperature from 25 to 15° C. An extrapolation of τ(c) to a further lower temperature (5° C) may lead to a τ(c) of ∼19 ns that would correspond to a τ(c) value of a tetrameric M-crystallin. These results also validate the observed changes in the hydrodynamic radius of M-crystallin, determined using DLS data. Further, the temperature-dependent protein dynamics of M-crystallin reveal considerable variation at/near the Ca(2+)-binding sites. A concerted analysis of the temperature dependent relaxation parameters and DLS data reveals that the self-association of the protein is not only a monomer-dimer equilibrium, but also goes to tetramers or other multimeric states. These higher states may co-exist in fast exchange with the monomeric and dimeric M-crystallin at milli-molar to sub-millimolar concentrations and at lower temperature.

Root-mean-square-deviation-based rapid backbone resonance assignments in proteins.

We have shown that the methodology based on the estimation of root-mean-square deviation (RMSD) between two sets of chemical shifts is very useful to rapidly assign the spectral signatures of (1)H(N), (13)C(α), (13)C(ß), (13)C', (1)H(α) and (15)N spins of a given protein in one state from the knowledge of its resonance assignments in a different state, without resorting to routine established procedures (manual and automated). We demonstrate the utility of this methodology to rapidly assign the 3D spectra of a metal-binding protein in its holo-state from the knowledge of its assignments in apo-state, the spectra of a protein in its paramagnetic state from the knowledge of its assignments in diamagnetic state and, finally, the spectra of a mutant protein from the knowledge of the chemical shifts of the corresponding wild-type protein. The underlying assumption of this methodology is that, it is impossible for any two amino acid residues in a given protein to have all the six chemical shifts degenerate and that the protein under consideration does not undergo large conformational changes in going from one conformational state to another. The methodology has been tested using experimental data on three proteins, M-crystallin (8.5 kDa, predominantly ß-sheet, for apo- to holo-state), Calbindin (7.5 kDa, predominantly α-helical, for diamagnetic to paramagnetic state and apo to holo) and EhCaBP1 (14.3 kDa, α-helical, the wild-type protein with one of its mutant). In all the cases, the extent of assignment is found to be greater than 85%.

Complete backbone assignment of a Ca2+-binding protein of the betagamma-crystallin superfamily from Methanosarcina acetivorans, at two denaturant concentrations.

We report here almost complete backbone assignment of a Ca(2+)-binding protein of the betagamma-crystallin superfamily from Methanosarcina acetivorans, at two denaturant (GdmCl) concentrations, using double and triple resonance experiments. These NMR assignments will be useful to understand the unfolding path of this protein.