Peptides with More than One 106-amino Acid Sequence Motif Are Needed to Mimic the Structural Stability of Spectrin

Menhart, Nick; Mitchell, Tracy; Lusitani, Denise; Topouzian, Nancy; Fung, Leslie W.‐M.

doi:10.1074/jbc.271.48.30410

Cited by 30 publications

(66 citation statements)

References 33 publications

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“…Purification procedures were as previously discussed (25,32), except that the buffers for the FPLC MonoQ purification were changed to 25 mM bis-Tris at pH 6.0 and the NaCl concentration was changed to 500 mM. Peptide identity was checked by SDS-polyacrylamide gel electrophoresis and amino-terminal sequencing (Biocore Facility, University of Notre Dame, South Bend, IN).…”

Section: Methodsmentioning

confidence: 99%

“…These peptides were expressed as glutathione S-transferase fusion proteins in Escherichia coli and released by thrombin cleavage with soluble thrombin (32). Purification procedures were as previously discussed (25,32), except that the buffers for the FPLC MonoQ purification were changed to 25 mM bis-Tris at pH 6.0 and the NaCl concentration was changed to 500 mM.…”

Section: Methodsmentioning

confidence: 99%

“…Preparation and Analysis of ␤-Spectrin and of ␣-Spectrin PeptidesSpectrin dimer was obtained by low ionic strength extraction of erythrocyte ghosts at 37°C, followed by molecular exclusion chromatography, as described previously (32). ␤-spectrin was obtained from spectrin dimer as before (21), except that ␤-spectrin was purified on the FPLC system using MonoQ column (Amersham Pharmacia Biotech) and NaCl gradient.…”

Section: Methodsmentioning

confidence: 99%

“…Fidelity of the polymerase-mediated reactions was subsequently confirmed by direct DNA sequencing. Genes encoding for the peptides Sp␣-(1-368), Sp␣-(1-262), Sp␣-(1-156), and Sp␣-(52-368) were prepared as described previously (25,32). The genes encoding for the peptides Sp␣-(12-368), Sp␣-(22-368), and Sp␣-(37-368) were derived from the gene for Sp␣-(1-368).…”

Section: Methodsmentioning

confidence: 99%

“…The molecular masses of these peptides were determined by mass spectrometry using electrospray ionization techniques (Washington University, St. Louis, MO). Protein concentrations were determined with absorbance values at 280 nm, using extinction coefficients determined from the primary sequence (32). In order to determine whether the peptides formed aggregates in buffer solution (5 mM phosphate buffer with 150 mM NaCl at pH 7.4), the solution molecular masses of the peptides at 1-2 mg/ml were determined at 4°C with an absolute molecular mass determination instrument based on multiangle (15 and 90°) light scattering (PD2000; Precision Detectors, Inc., Amherst, MA) as described previously (32).…”

Section: Methodsmentioning

confidence: 99%

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Interactions of the α-Spectrin N-terminal Region with β-Spectrin

Cherry

Menhart

Fung

1999

Journal of Biological Chemistry

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Spectrin of the erythrocyte membrane skeleton is composed of ␣-and ␤-spectrin, which associate to form heterodimers and tetramers. It has been suggested that a fractional domain (helix C) in the amino-terminal region of ␣-spectrin (N␣ region) bundles with another fractional domain in the carboxyl-terminal region of ␤-spectrin (C␤ region) to yield a triple ␣-helical bundle and that this helical bundling is largely responsible for tetramer formation. However, there are certain objections to assigning a preeminent role to this helical bundling in the tetramerization reactions. We prepared several recombinant peptides of ␣-spectrin fragments spanning only the N␣ region (lacking the dimer nucleation site) and quantitatively studied their interaction with ␤-spectrin. We found that a majority of the interactions were localized, as expected, in the N␣-helix C region but that there was also some contribution from the nonhomologous region. More importantly, the temperature and ionic strength dependence of this interaction in our model peptides was different from that in intact spectrin. We suggest that, although the regions involving the putative helical bundling in ␣-and ␤-spectrin undoubtedly play a significant role in tetramerization, regions distal to the N␣-helix C region in spectrin are also involved in tetramer formation. Structural flexibility and lateral interactions may play a role in spectrin tetramerization.Spectrin is the major component of the erythrocyte membrane skeleton and is thought to be largely responsible for the red blood cell's unique flexibility and deformability (1). Spectrin is composed of two subunits, ␣-spectrin (280 kDa) and ␤-spectrin (246 kDa), which associate to form ␣␤ heterodimers (2, 3), which then associate to form the biologically relevant (␣␤) 2 tetramers and higher order oligomers (4 -6). The tetramer exists as a flexible rodlike molecule that is anchored to the erythrocyte membrane by interactions with certain membrane proteins, most importantly band 3 and band 4.1 (7). This spectrin network imparts mechanical stability to erythrocytes. Erythrocyte membranes in patients suffering from hereditary spherocytosis and hereditary elliptocytosis exhibit unusually high mechanical fragility. A large subset of these diseases are known to be the result of defects in spectrin (8 -11).Amino acid (12) and cDNA (13) sequence analyses show that both ␣-and ␤-spectrin are largely composed of multiple homologous motifs of about 106 amino acid residues. These sequence motifs are suggested to fold into triple ␣-helical bundles (structural domains) with the first and third helices parallel and the intervening second helix antiparallel (14). This proposed structure is supported by recent x-ray (15) and NMR (16) studies of various recombinant spectrin fragments, as well as by spectroscopic studies of intact spectrin (17-19). The three helices show a pronounced amphipathic character, and the resulting triple-␣-helical bundle structure is thought to be stabilized by the sequestration of the hydrophobic face...

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Interactions of the α-Spectrin N-terminal Region with β-Spectrin

Cherry

Menhart

Fung

1999

Journal of Biological Chemistry

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Localizing the chaperone activity of erythroid spectrin

Bose

Chakrabarti

2019

Cytoskeleton

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Spectrin, the major protein of the erythrocyte membrane skeleton has canonically been thought to only serve a structural function. We have previously described a novel chaperone‐like property of spectrin and also hypothesized that the chaperone activity and binding of a hydrophobic ligand, Prodan are localized in the self‐association domain. Here we probe the location and molecular origin of the chaperone activity of multi‐domain spectrin using a selection of individual recombinant spectrin domains, which we have characterized using intrinsic tryptophan fluorescence and CD spectroscopy to show their identity to native spectrin. Aggregation assays using insulin, ADH, α‐ and β‐globin as well as enzyme refolding assays using alkaline phosphatase and α‐glucosidase show that the chaperone activity is not only localized in the self‐association domain but is a generalized property of spectrin domains. This is to our understanding, a unique feature in the case of modular multi‐repeat proteins, possibly implicating that the large family of “spectrin‐repeat” domain containing proteins may also have chaperone like property. Substrate selectivity of chaperone activity as evidenced by the preferential protection of α‐ over β‐globin chains is seen; which has implications in hemoglobin diseases. Moreover, enzyme‐refolding assays also indicate alternate modes of chaperone action. We propose that the molecular origin of chaperone activity resides in the surface exposed hydrophobic patches of the spectrin domains as shown by ANS (1‐anilinonaphthalene‐8‐sulfonic acid) and Prodan (6‐propionyl‐2[dimethylamino]‐naphthalene) binding. We also show that Prodan does indeed have a unique binding site on spectrin located at the self‐association domain.

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