Abstract
Leucine aminopeptidases (LAPs) are present in animals, plants, and microbes. In plants, there are two classes of LAPs. The neutral LAPs (LAP-N and its orthologs) are constitutively expressed and detected in all plants, whereas the stress-induced acidic LAPs (LAP-A) are expressed only in a subset of the Solanaceae. LAPs have a role in insect defense and act as a regulator of the late branch of wound signaling in Solanum lycopersicum (tomato). Although the mechanism of LAP-A action is unknown, it has been presumed that LAP peptidase activity is essential for regulating wound signaling. Here we show that plant LAPs are bifunctional. Using three assays to monitor protein protection from heat-induced damage, it was shown that the tomato LAP-A and LAP-N and the Arabidopsis thaliana LAP1 and LAP2 are molecular chaperones. Assays using LAP-A catalytic site mutants demonstrated that LAP-A chaperone activity was independent of its peptidase activity. Furthermore, disruption of the LAP-A hexameric structure increased chaperone activity. Together, these data identify a new class of molecular chaperones and a new function for the plant LAPs as well as suggesting new mechanisms for LAP action in the defense of solanaceous plants against stress.
Highlights
The tomato leucine aminopeptidase (LAP) regulates wound signaling, and its mode of action is unknown
The restriction enzyme NdeI was heated for 90 min at 43 °C either alone, with lysozyme or protein A, with PsHsp18.1, or with His6-LAPs with acidic pIs (LAP-A) (0.2–2.0 M)
The level of His6-LAP-A chaperone activity was similar to that reported for the bovine ␣-crystallins [39]
Summary
The tomato leucine aminopeptidase (LAP) regulates wound signaling, and its mode of action is unknown. Results: Plant LAPs are molecular chaperones, and the chaperone activity of the tomato LAP-A is independent of its peptidase and enhanced upon hexamer disruption. Disruption of the LAP-A hexameric structure increased chaperone activity Together, these data identify a new class of molecular chaperones and a new function for the plant LAPs as well as suggesting new mechanisms for LAP action in the defense of solanaceous plants against stress. A catalytically inactive LAP-N was impaired in chaperone activity These data shed new light on the complexity of plant LAPs and suggest new potential roles for LAPs in defending tomato against stress
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