Manashi Sherawat scite author profile

Playing tag with terbium: New hydrophobic contacts and ligating amino acids are revealed in the 2.0‐Å resolution X‐ray crystal structure of a chemically evolved 17‐residue lanthanide‐binding peptide complexed with a Tb3+ ion (see ribbon diagram). The crystal structure agrees well with luminescence‐lifetime measurements in solution, which indicate that no first‐shell‐coordinating water molecules are present in the complex.

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Structural Origin of the High Affinity of a Chemically Evolved Lanthanide‐Binding Peptide

Nitz

Sherawat

Franz

et al. 2004

Angewandte Chemie

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Structure of a rabbit muscle fructose-1,6-bisphosphate aldolase A dimer variant

Sherawat

Tolan

Allen

2008

Acta Crystallogr D Biol Cryst

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Fructose‐1,6‐bisphosphate aldolase (aldolase) is an essential enzyme in glycolysis and gluconeogenesis. In addition to this primary function, aldolase is also known to bind to a variety of other proteins, a property that may allow it to perform `moonlighting' roles in the cell. Although monomeric and dimeric aldolases possess full catalytic activity, the enzyme occurs as an unusually stable tetramer, suggesting a possible link between the oligomeric state and these noncatalytic cellular roles. Here, the first high‐resolution X‐ray crystal structure of rabbit muscle D128V aldolase, a dimeric form of aldolase mimicking the clinically important D128G mutation in humans associated with hemolytic anemia, is presented. The structure of the dimer was determined to 1.7 Å resolution with the product DHAP bound in the active site. The turnover of substrate to produce the product ligand demonstrates the retention of catalytic activity by the dimeric aldolase. The D128V mutation causes aldolase to lose intermolecular contacts with the neighboring subunit at one of the two interfaces of the tetramer. The tertiary structure of the dimer does not significantly differ from the structure of half of the tetramer. Analytical ultracentrifugation confirms the occurrence of the enzyme as a dimer in solution. The highly stable structure of aldolase with an independent active site is consistent with a model in which aldolase has evolved as a multimeric scaffold to perform other noncatalytic functions.

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Structure of the complex of trypsin with a highly potent synthetic inhibitor at 0.97 Å resolution

Sherawat¹,

Kaur²,

Perbandt³

et al. 2007

Acta Crystallogr D Biol Cryst

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The structure of the complex formed between bovine beta-trypsin and the highly potent synthetic inhibitor 2-{3'-[5'-methoxy-2'-(N-p-diaminomethylphenyl)amido]-1'-pyrido}-5-(N-2''-t-butylethanol)amidobenzoic acid (C(28)H(32)N(5)O(6)) has been determined at 0.97 A resolution. X-ray intensity data were collected to 0.97 A under cryocooled conditions. The structure was refined anisotropically using REFMAC5 and SHELX-97 to R(cryst) factors of 13.4 and 12.6% and R(free) factors of 15.7 and 16.3%, respectively. Several regions of the main chain and side chains that have not been previously observed were clearly defined in the present structure. H atoms are indicated as significant peaks in an |F(o) - F(c)| difference map, which accounts for an estimated 35% of all H atoms at the 2.5sigma level. The C, N and O atoms are definitively differentiated in the electron-density maps. The amido part of the inhibitor occupies the specificity pocket and the remainder fills the remaining part of the ligand-binding cleft and interacts with the enzyme through an extensive network of hydrogen bonds. The inhibitor distorts the stereochemistry of the catalytic triad, Ser195-His57-Asp102, thereby blocking the proton-relay process of the active site by preventing the formation of the crucial hydrogen bond between His57 N(delta1) and Asp102 O(delta1).

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Crystal Structure of the complex formed between trypsin and a designed synthetic highly potent inhibitor in the presence of benzamidine at 0.97 A resolution

Sherawat¹,

Kaur²,

Perbandt³

et al. 2006

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