Mónica Rodríguez de la Vega scite author profile

Corn earworm (Helicoverpa zea), also called tomato fruitworm, is a common pest of many Solanaceous plants. This insect is known to adapt to the ingestion of plant serine protease inhibitors by using digestive proteases that are insensitive to inhibition. We have now identified a B-type carboxypeptidase of H. zea (CPBHz) insensitive to potato carboxypeptidase inhibitor (PCI) in corn earworm. To elucidate the structural features leading to the adaptation of the insect enzyme, the crystal structure of the recombinant CPBHz protein was determined by x-ray diffraction. CPBHz is a member of the A͞B subfamily of metallocarboxypeptidases, which displays the characteristic metallocarboxypeptidase ␣͞␤-hydrolase fold, and does not differ essentially from the previously described Helicoverpa armigera CPA, which is very sensitive to PCI. The data provide structural insight into several functional properties of CPBHz. The high selectivity shown by CPBHz for C-terminal lysine residues is due to residue changes in the S1 substrate specificity pocket that render it unable to accommodate the side chain of an arginine. The insensitivity of CPBHz to plant inhibitors is explained by the exceptional positioning of two of the main regions that stabilize other carboxypeptidase-PCI complexes, the ␤8-␣9 loop, and ␣7 together with the ␣7-␣8 loop. The rearrangement of these two regions leads to a displacement of the active-site entrance that impairs the proper interaction with PCI. This report explains a crystal structure of an insect protease and its adaptation to defensive plant protease inhibitors.crystal structure ͉ inhibitor resistance ͉ Helicoverpa zea ͉ metallocarboxypeptidase T he larvae of plant-eating insects have a high need for free amino acids and nitrogen during their development. Normally, they meet these requirements by degrading dietary proteins. The digestive enzymes present in the larvae of the lepidopteran insects such as Helicoverpa zea are closely related to those secreted from the mammalian pancreas, comprising serine endopeptidases like trypsins and chymotrypsins and exopeptidases such as metallocarboxypeptidases and aminopeptidases (1, 2).Plants have evolved a defense that interferes with the insects' digestive system by expressing a number of different protease inhibitors (PIs), which are either constitutively present or strongly up-regulated in response to wound damage (3). Most PIs are small proteins that have been found in all plant species investigated thus far and occur in both reproductive and vegetative tissues. In herbivorous insects, they act by inhibiting protein digestive enzymes in the guts of insect larvae or adults, resulting in amino acid deficiencies that lead to serious developmental delay, mortality, or reduced fecundity.A number of polyphagous insects, among them H. zea, a common pest of many Solanaceous plants such as the potato (4), have adapted to the protease inhibitors of their various host plants. Their survival and larval development is not affected by the presence of such molecules in th...

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Nnal‐like proteins are active metallocarboxypeptidases of a new and diverse M14 subfamily

Vega

Sevilla²,

Hermoso

et al. 2007

FASEB j.

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Nna1 has some sequence similarity to metallocarboxypeptidases, but the biochemical characterization of Nna1 has not previously been reported. In this work we performed a detailed genomic scan and found >100 Nna1 homologues in bacteria, Protista, and Animalia, including several paralogs in most eukaryotic species. Phylogenetic analysis of the Nna1-like sequences demonstrates a major divergence between Nna1-like peptidases and the previously known metallocarboxypeptidases subfamilies: M14A, M14B, and M14C. Conformational modeling of representative Nna1-like proteins from a variety of species indicates an unusually open active site, a property that might facilitate its action on a wide variety of peptide and protein substrates. To test this, we expressed a recombinant form of one of the Nna1-like peptidases from Caenorhabditis elegans and demonstrated that this protein is a fully functional metallocarboxypeptidase that cleaves a range of C-terminal amino acids from synthetic peptides. The enzymatic activity is activated by ATP/ADP and salt-inactivated, and is preferentially inhibited by Z-Glu-Tyr dipeptide, which is without precedent in metallocarboxypeptidases and resembles tubulin carboxypeptidase functioning; this hypothesis is strongly reinforced by the results depicted in Kalinina et al. published as accompanying paper in this journal. Our findings demonstrate that the M14 family of metallocarboxypeptidases is more complex and diverse than expected, and that Nna1-like peptidases are functional variants of such enzymes, representing a novel subfamily (we propose the name M14D) that contributes substantially to such diversity.

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The novel structure of a cytosolic M14 metallocarboxypeptidase (CCP) from Pseudomonas aeruginosa : a model for mammalian CCPs

et al. 2012

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PaCCP is a metallocarboxypeptidase (MCP) of the M14 family from Pseudomonas aeruginosa, which belongs to a bacterial clade of carboxypeptidases that are homologous to the recently discovered M14D subfamily of human nonsecretory cytosolic carboxypeptidases (CCPs). CCPs are intracellular peptidases involved, among other roles, in the post-translational modifications of tubulin. Here we report the crystal structure of PaCCP at high resolution (1.6 Å). Its 375 residues are folded in a novel β-sandwich N-terminal domain followed by the classical carboxypeptidase α/β-hydrolase domain, this one in a shorter and more compact form. The former is unique in the whole family and does not have sequential or structural homology with other domains that are usually flanking the latter, like the prodomain of the M14A subfamily or the C-terminal transthyretin/prealbumin-like domains of the M14B subfamily. PaCCP does not display activity against small carboxypeptidase substrates, so in this form it might constitute an inactive precursor of the protease. Structural results derived from cocrystallization with well-known inhibitors of MCPs indicate that the enzyme might only possess C-terminal hydrolase activity against cellular substrates of particular specificity and/or when undergoes structural rearrangements. The derived PaCCP structure allows a first structural insight into the more complex and largely unknown mammalian CCP subfamily.

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Response of the digestive system of Helicoverpa zea to ingestion of potato carboxypeptidase inhibitor and characterization of an uninhibited carboxypeptidase B

Bayés¹,

Vega²,

Vendrell³

et al. 2006

Insect Biochemistry and Molecular Biology

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