Maria A. Castiglione Morelli

Three−dimensional structure and stability of the KH domain: molecular insights into the fragile X syndrome

The KH module is a sequence motif found in a number of proteins that are known to be in close association with RNA. Experimental evidence suggests a direct involvement of KH in RNA binding. The human FMR1 protein, which has two KH domains, is associated with fragile X syndrome, the most common inherited cause of mental retardation. Here we present the three-dimensional solution structure of the KH module. The domain consists of a stable beta alpha alpha beta beta alpha fold. On the basis of our results, we suggest a potential surface for RNA binding centered on the loop between the first two helices. Substitution of a well-conserved hydrophobic residue located on the second helix destroys the KH fold; a mutation of this position in FMR1 leads to an aggravated fragile X phenotype.

Solution structure of human calcitonin in membrane‐mimetic environment: The role of the amphipathic helix

The 32 amino acid hormone human calcitonin was studied at pH 3.7 and 7.4 by multidimensional NMR spectroscopy in sodium dodecyl sulfate micelles at 310K. The secondary structure was obtained from nuclear Overhauser enhancement spectroscopy (NOESY), 3JHNα coupling constants, and slowly exchanging amide data. Three‐dimensional structures consistent with NMR data were generated by using distance geometry calculations. A set of 265 interproton distances derived from NOESY experiments, hydrogen‐bond constraints obtained from amide exchange, and coupling constants were used. From the initial random conformations, 30 distance geometry structures with minimal violations were selected for further refinement with restrained energy minimization. In micelles, at both pHs, the hormone assumes an amphipathic α‐helix from Leu9 to Phe16, followed by a type‐I β‐turn between residues Phe16 and Phe19. From His20 onward the molecule is extended and no interaction with the helix was observed. The relevance of the amphipathic helix for the structure–activity relationship, the possible mechanisms of interaction with the receptor, as well as the formation of fibrillar aggregates, is discussed. Proteins 32:314–323, 1998.

Structure-Activity Relationship of the Leucine-based Sorting Motifs in the Cytosolic Tail of the Major Histocompatibility Complex-associated Invariant Chain

The cytosolic tail of the major histocompatibility complex-associated invariant chain protein contains two Leu-based motifs that both mediate efficient sorting to the endocytic pathway. Nuclear magnetic resonance data on a peptide of 27 residues corresponding to the cytosolic tail of human invariant chain indicate that in water at pH 7.4 the membrane distal motif Leu7-Ile8 lies within a nascent helix, while the membrane proximal motif Met16-Leu17 is part of a turn. The presence of a small amount of methanol stabilizes an α helix from Gln4 to Leu17 with a kink on Pro15. Point mutations of the cytosolic tail of the protein suggest that amino-terminal residues located in spatial proximity to the Leu motifs contribute to efficient internalization and targeting to endosomes in transfected COS cells. Residues on the spatially opposite side of the Leu motifs were, on the other hand, mutated with no measurable effect on targeting. Structural and biological data thus suggest that the signals are not continuous but consist of “signal patches” formed by the three-dimensional structure of the cytosolic tail of invariant chain.

Structural determinants of salmon calcitonin bioactivity: the role of the Leu-based amphipathic alpha-helix.

Salmon calcitonin (sCT) forms an amphipathic helix in the region 9–19, with the C-terminal decapeptide interacting with the helix (Amodeo, P., Motta, A., Strazzullo, G., Castiglione Morelli, M. A. (1999) J. Biomol. NMR 13, 161–174). To uncover the structural requirements for the hormone bioactivity, we investigated several sCT analogs. They were designed so as to alter the length of the central helix by removal and/or replacement of flanking residues and by selectively mutating or deleting residues inside the helix. The helix content was assessed by circular dichroism and NMR spectroscopies; the receptor binding affinity in human breast cancer cell line T 47D and the in vivo hypocalcemic activity were also evaluated. In particular, by NMR spectroscopy and molecular dynamics calculations we studied Leu23,Ala24-sCT in which Pro23 and Arg24 were replaced by helix inducing residues. Compared with sCT, it assumes a longer amphipathic α-helix, with decreased binding affinity and one-fifth of the hypocalcemic activity, therefore supporting the idea of a relationship between a definite helix length and bioactivity. From the analysis of other sCT mutants, we inferred that the correct helix length is located in the 9–19 region and requires long range interactions and the presence of specific regions of residues within the sequence for high binding affinity and hypocalcemic activity. Taken together, the structural and biological data identify well defined structural parameters of the helix for sCT bioactivity.

The KH module has an αβ fold

The KH module has recently been identified in a number of RNA associated proteins including vigilin and FMR1, a protein implicated in the fragile X syndrome. In this work, NMR spectroscopy was used to determine the secondary structure in solution of a KH domain (repeat 5 from vigilin). Almost complete assignments were obtained for the 1H and 15N resonances using uniform 15N‐labeling of the protein combined with homo‐nuclear 2D 1HNMR and 3D 15N correlated 1H NMR. On the basis of NOE patterns, secondary chemical shifts and amide solvent exposure, the secondary structure consists of an antiparallel three stranded β sheet connected by two helical regions. This domain may also be stabilized by an appended C‐terminal helix which is common to many but not all members of the KH family.

Dynamic properties of salmon calcitonin bound to sodium dodecyl sulfate micelles: A restrained molecular dynamics study from NMR data

SummaryWe have investigated the conformational behaviour of salmon calcitonin bound to sodium dodecyl sulfate micelles by means of restrained molecular dynamics simulations with both ‘static’ and time-averagen NMR distance restraints. A more realistic picture of the inherent flexibility of the hormone is obtained when using time averaging. With this apprach. long-range NOEs are interpreted better considering a dynamical exchange among different conformations.

A new triple-stranded α-helical bundle in solution: the assembling of the cytosolic tail of MHC-associated invariant chain

BACKGROUND The invariant chain (li) is a transmembrane protein that associates with the major histocompatibility complex class II (MHC II) molecules in the endoplasmic reticulum. The cytosolic tail of li contains two leucine-based sorting motifs and is involved in sorting the MHC II molecules to the endosomal pathway where the peptide antigen is bound. This region of li also contributes to phenotypical changes in cells, such as the formation of large endocytic structures. RESULTS We report here the three-dimensional structure of a 27 amino acid peptide corresponding to the cytosolic tail of li. The structure was determined by nuclear magnetic resonance (NMR) spectroscopy using a computational strategy. At high concentration, this structure reveals a new triple-stranded alpha-helical bundle in which the helices, two parallel and one antiparallel, are almost coplanar. Trimerization is mediated by electrostatic interactions intercalated by three hydrophobic layers. CONCLUSIONS The new trimer fold, the first to be identified by NMR data alone, can be used to improve understanding of protein-protein interactions and to model multiple-helical transmembrane proteins and receptors. We suggest that interactions of the li cytosolic tails may form part of a mechanism that could cause the endosomal retention and enlarged endosomes induced by li.