In modern agriculture and weed management
practices, herbicides
have been widely used to control weeds effectively and represent more
than 50% of commercial pesticides applied in the world. Herbicides
with unique mechanisms of actions (MOA) have historically been discovered
and commercialized every two or three years from the 1950s to the
1980s. However, this trend lowered dramatically as no herbicide with
a novel MOA has been marketed for more than 30 years. The fast-growing
resistance to commercial herbicides has reignited the agricultural
chemical industry interest in new structural scaffolds targeting novel
sites in plants. Carbon–phosphorus bonds (C–P) containing
natural products (NPs) have played an essential role in herbicide
discovery as the chemical diversity, and the promising bioactivity
of natural C–P phytotoxins can provide exciting opportunities
for the discovery of both natural and semisynthetic herbicides with
novel targets. Among commercial herbicides, glyphosate (Roundup),
a famous C–P containing herbicide, is by far the most universally
used herbicide worldwide. Furthermore, glufosinate is one of the most
widely used natural herbicides in the world. Therefore, C–P
NPs are a treasure for discovering new herbicides with novel mechanisms
of actions (MOAs). Here, we present an overview of the chemistry and
biology of glufosinate including isolation and characterization, mode
of action, herbicidal use, biosynthesis, and chemical synthesis since
its discovery in order to not only help scientists reassess the role
of this famous herbicide in the field of agrichemical chemistry but
also build a new stage for discovering novel C–P herbicides
with new MOAs.
Linaridins
and lanthipeptides are two classes of natural products
belonging to the ribosomally synthesized and posttranslationally modified
peptide (RiPP) superfamily. Although these two RiPP classes share
similar structural motifs such as dehydroamino acids and thioether-based
cross-links, the biosynthesis of linaridins and lanthipeptides involved
distinct sets of enzymes. Here, we report the identification of a
novel lanthipeptide cypepeptin from a recombinant strain of Streptomyces lividans, which harbors most of the
cypemycin (a prototypic linaridin) biosynthetic gene cluster but lacks
the decarboxylase gene cypD. In contrast to the generally
believed structure of cypemycin, multiple d-amino acids and
Z-dehydrobutyrines were observed in both cypepeptin and cypemycin,
and the stereochemistry of each amino acid was established by the
extensive structural analysis in combination with genetic knockout
and mutagenesis studies. Comparative analysis of cypemycin and cypepeptin
showed that the aminovinyl-cysteine (AviCys) moiety of cypemycin plays
an essential role in disrupting the cell integrity of M. luteus, which cannot be functionally substituted
by the structurally similar lanthionine moiety.
Fungi are a source of novel phytotoxic compounds to be explored in the search for effective and environmentally safe herbicides. The genetic inactivation of the biosynthetic pathway of the new phytotoxin cichorine has led to the isolation of three novel phytotoxins from the fungus Aspergillus nidulans: 8-methoxycichorine (4), 8-epi-methoxycichorine (5), and N-(4’-carboxybutyl) cichorine (6). The structure of the new compounds was clearly determined by a combination of nuclear magnetic resonance (NMR) analysis and high-resolution electrospray ionization (HRESIMS). The phytotoxic bioassay was studied on leaves from Zea mays and Medicago polymorpha L. at the concentration of 5 × 10−3 M by using a moist chamber technique. Novel phytotoxins 8-methoxycichorine (4), 8-epi-methoxycichorine (5), and N-(4’-carboxybutyl) cichorine (6) exhibited a better phytotoxic effect than cichorine.
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