ChemInform Abstract: CHEMISTRY AND BIOCHEMISTRY OF MICROBIAL α‐GLUCOSIDASE INHIBITORS

Truscheit, Ernst; Frommer, W.; Junge, Bodo; Mueller, Lisa S.; Schmidt, Delf; Wingender, W.

doi:10.1002/chin.198151383

Cited by 25 publications

(33 citation statements)

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“…The binding of acarbose to glucoamylase was reported earlier; the binding to GLA1 being found stronger than to GLU1, moreover, it was ten times stronger than to Aspergillus niger (Aspni) glucoamylase (Solovicova et al 1999). Interestingly, the IC50 of GLL1 is ∼100 times higher than that of Aspni glucoamylase, which is 0.04 µg/mL (0.06 µM) (Truscheit et al 1981). This finding indicates that the character of GLL1 upon the binding of acarbose resembles that of GLU1.…”

Section: Characterization Of Gll1supporting

confidence: 69%

Biochemical characterization of a glucoamylase from Saccharomycopsis fibuligera R64

et al. 2010

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Glucoamylase from the yeast Saccharomycopsis fibuligera R64 (GLL1) has successfully been purified and characterized. The molecular mass of the enzyme was 56,583 Da as determined by mass spectrometry. The purified enzyme demonstrated optimum activity in the pH range of 5.6-6.4 and at 50• C. The activity of the enzyme was inhibited by acarbose with the IC50 value of 5 µM. GLL1 shares high amino acid sequence identity with GLU1 and GLA1, which are Saccharomycopsis fibuligera glucoamylases from the strains HUT7212 and KZ, respectively. The properties of GLL1, however, resemble that of GLU1. The elucidation of the primary structure of GLL1 contributes to the explanation of this finding.

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Section: Characterization Of Gll1supporting

confidence: 69%

Biochemical characterization of a glucoamylase from Saccharomycopsis fibuligera R64

et al. 2010

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“…Such mC 7 N units were also found in ansamycins of the 'benzenic' type, such as geldanamycin 5 and the maytansinoids, 6 and in the unrelated family of the mitomycin antibiotics ( Figure 1). 7 A number of other compounds also seemed to contain mC 7 N units, such as validamycin 8 and acarbose, 9 pactamycin, 10 as well as asukamycin 11 and the manumycins, 12 and were proposed to have a similar biosynthetic origin. 11,13 However, subsequent work has shown their origins to be different.…”

Section: Historymentioning

confidence: 99%

The biosynthesis of 3-amino-5-hydroxybenzoic acid (AHBA), the precursor of mC7N units in ansamycin and mitomycin antibiotics: a review

2010

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The aminoshikimate pathway of formation of 3-amino-5-hydroxybenzoic acid (AHBA), the precursor of ansamycin and other antibiotics is reviewed. In this biosynthesis, genes for kanosamine formation have been recruited from other genomes, to provide a nitrogenous precursor. Kanosamine is then phosphorylated and converted by common cellular enzymes into 1-deoxy-1-imino-erythrose 4-phosphate, the substrate for the formation of aminoDAHP. This is converted via 5-deoxy-5-aminodehydroquinic acid and 5-deoxy-5-aminodehydroshikimic acid into AHBA. Remarkably, the pyridoxal phosphate enzyme AHBA synthase seems to have two catalytic functions: As a homodimer, it catalyzes the last reaction in the pathway, the aromatization of 5-deoxy-5-aminodehydroshikimic acid, and at the beginning of the pathway in a complex with the oxidoreductase RifL it catalyzes the transamination of UDP-3-keto-D-glucose. The AHBA synthase gene also serves as a useful tool in the genetic screening for new ansamycins and other AHBA-derived natural products.

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“…The digestion of starch occurs in several stages in humans (Truscheit et al, 1981;Semenza, 1987). Initially salivary a-amylase provides a partial digestion, which breaks down polymeric starch into shorter oligomers.…”

Section: Introductionmentioning

confidence: 99%

“…The salivary and pancreatic a-amylases are highly homologous in terms of primary sequence (Nishide et al, 1986) but d o exhibit somewhat different cleavage patterns (Minamiura, 1988). The functional differences observed undoubtedly arise from the 15 amino Reprint requests to: Gary D. Brayer, Department of Biochemistry and Molecular Biology, University of British Columbia, Vancouver, British Columbia V6T 123, Canada; acid substitutions between these sequences, some of which occur in the putative active site region.The digestion of starch occurs in several stages in humans (Truscheit et al, 1981;Semenza, 1987). Initially salivary a-amylase provides a partial digestion, which breaks down polymeric starch into shorter oligomers.…”

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confidence: 99%

The structure of human pancreaticα-amylase at 1.8 Å resolution and comparisons with related enzymes

1995

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The structure of human pancreatic a-amylase has been determined to 1.8 A resolution using X-ray diffraction techniques. This enzyme is found to be composed of three structural domains. The largest is Domain A (residues 1-99, 169-404), which forms a central eight-stranded parallel @-barrel, to one end of which are located the active site residues Asp 197, Glu 233, and Asp 300. Also found in this vicinity is a bound chloride ion that forms ligand interactions to Arg 195, Asn 298, and Arg 337. Domain B is the smallest (residues 100-168) and serves to form a calcium binding site against the wall of the @-barrel of Domain A. Protein groups making ligand interactions to this calcium include Asn 100, Arg 158, Asp 167, and His 201. Domain C (residues 405-496) is made up of antiparallel @-structure and is only loosely associated with Domains A and B. It is notable that the N-terminal glutamine residue of human pancreatic a-amylase undergoes a posttranslational modification to form a stable pyrrolidone derivative that may provide protection against other digestive enzymes. Structure-based comparisons of human pancreatic a-amylase with functionally related enzymes serve to emphasize three points. Firstly, despite this approach facilitating primary sequence alignments with respect to the numerous insertions and deletions present, overall there is only -15% sequence homology between the mammalian and fungal a-amylases. Secondly, in contrast, these same studies indicate that significant structural homology is present and of the order of -70%. Thirdly, the positioning of Domain C can vary considerably between a-amylases. In terms of the more closely related porcine enzyme, there are four regions of polypeptide chain (residues 237-250, 304-310, 346-354, and 458-461) with significantly different conformations from those in human pancreatic a-amylase. At least two of these could play a role in observed differential substrate and cleavage pattern specificities between these enzymes. Similarly, amino acid differences between human pancreatic and salivary a-amylases have been localized and a number of these occur in the vicinity of the active site.Keywords: amylase; crystallography; enzymology; glycogen; pancreatic; sequences; starch; structure a-Amylases catalyze the hydrolysis of a-1,4 glucan linkages in starch and are widely distributed in nature, being found in bacteria, plants and animals. In humans, a-amylase is composed of 496 amino acids in a single polypeptide chain, which is encoded on chromosome 1 as part of a multigene family (Gumucio et al., 1988). These genes are regulated so that different isozymes are synthesized in either salivary glands or the pancreas. The salivary and pancreatic a-amylases are highly homologous in terms of primary sequence (Nishide et al., 1986) but d o exhibit somewhat different cleavage patterns (Minamiura, 1988). The functional differences observed undoubtedly arise from the 15 amino Reprint requests to: Gary D. Brayer, Department of Biochemistry and Molecular Biology, University of B...

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ChemInform Abstract: CHEMISTRY AND BIOCHEMISTRY OF MICROBIAL α‐GLUCOSIDASE INHIBITORS

Cited by 25 publications

References 1 publication

Biochemical characterization of a glucoamylase from Saccharomycopsis fibuligera R64

Biochemical characterization of a glucoamylase from Saccharomycopsis fibuligera R64

The biosynthesis of 3-amino-5-hydroxybenzoic acid (AHBA), the precursor of mC7N units in ansamycin and mitomycin antibiotics: a review

The structure of human pancreaticα-amylase at 1.8 Å resolution and comparisons with related enzymes

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