Defence compounds in pollen: why do they occur and how do they affect the ecology and evolution of bees?

Pollen plays two important roles in angiosperm reproduction, serving as a vehicle for the plant’s male gametes, but also, in many species, as a lure for pollen-feeding animals. Despite being an important food source for many pollinators, pollen often contains compounds with known deterrent or toxic...

Full description

Saved in:
Bibliographic Details
Published in:The New phytologist 2020-02, Vol.225 (3), p.1053-1064
Main Authors: Forrest, Jessica R. K., Rivest, Sébastien
Format: Article
Language:English
Subjects:
Animals
Anti-Infective Agents - metabolism
Bees
Bees - physiology
Biological Evolution
Colonization
Consumers
defence compounds
Ecological and Environmental Phenomena
Food sources
Gametes
Hypotheses
Microorganisms
Models, Biological
Organic chemistry
Plant tissues
plant–pollinator interactions
Pleiotropy
Pollen
Pollen - chemistry
Pollen - immunology
pollen defence
pollen thieves
pollination
Pollinators
secondary metabolites
toxic pollen
Viewpoints
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Pollen plays two important roles in angiosperm reproduction, serving as a vehicle for the plant’s male gametes, but also, in many species, as a lure for pollen-feeding animals. Despite being an important food source for many pollinators, pollen often contains compounds with known deterrent or toxic properties, as documented in a growing number of studies. Here we review these studies and discuss the role of pollen defensive compounds in the coevolutionary relationship between plants and bees, the preeminent consumers of pollen. Next, we evaluate three hypotheses that may explain the existence of defensive compounds in pollen. The pleiotropy hypothesis, which proposes that defensive compounds in pollen merely reflect physiological spillover from other plant tissues, is contradicted by evidence from several species. Although plants may experience selection to defend pollen against poor-quality pollinators, we also find only partial support for the protection-against-pollen-collection-hypothesis. Finally, pollen defences might protect pollen from colonisation by antagonistic microorganisms (antimicrobial hypothesis), although data to evaluate this idea are scarce. Further research on the effects of pollen defensive compounds on pollinators, pollen thieves, and pollen-colonising microbes will be needed to understand why many plants have chemically defended pollen, and the consequences of those defences for pollen consumers.
ISSN:0028-646X
1469-8137
DOI:10.1111/nph.16230