Angewandte Chemie,
Год журнала:
2023,
Номер
136(1)
Опубликована: Ноя. 15, 2023
Abstract
Valanimycin
is
an
azoxy‐containing
natural
product
isolated
from
the
fermentation
broth
of
Streptomyces
viridifaciens
MG456‐hF10.
While
biosynthesis
valanimycin
has
been
partially
characterized,
how
azoxy
group
constructed
remains
obscure.
Herein,
membrane
protein
VlmO
and
putative
hydrazine
synthetase
ForJ
formycin
biosynthetic
pathway
are
demonstrated
to
catalyze
N−N
bond
formation
converting
O
‐(
l
‐seryl)‐isobutyl
hydroxylamine
into
N
‐(isobutylamino)‐
‐serine.
Subsequent
installation
shown
be
catalyzed
by
non‐heme
diiron
enzyme
VlmB
in
a
reaction
which
single
VlmO/ForJ
oxidized
four
electrons
yield
group.
The
catalytic
cycle
appears
begin
with
resting
μ‐oxo
diferric
complex
VlmB,
as
supported
Mössbauer
spectroscopy.
This
study
also
identifies
d
‐serine
alternative
substrate
for
leading
two
regioisomers.
reactions
kinase
VlmJ
lyase
VlmK
during
final
steps
established
well.
was
thus
fully
reconstituted
vitro
using
enzymes
VlmO/ForJ,
VlmK.
Importantly,
VlmB‐catalyzed
represents
first
example
enzyme‐catalyzed
expected
proceed
atypical
mechanism.
Branch-point
syntheses
in
nonribosomal
peptide
assembly
are
rare
but
useful
strategies
to
generate
tripodal
peptides
with
advantageous
hexadentate
iron-chelating
capabilities,
as
seen
siderophores.
However,
the
chemical
logic
underlying
branching
by
synthetase
(NRPS)
often
remains
complex
and
elusive.
Here,
we
review
common
for
biosynthesis
of
branched
(NRPs)
present
our
biochemical
investigation
on
NRPS-catalyzed
fimsbactin
A,
a
mixed-ligand
siderophore
produced
human
pathogenic
strain
Acinetobacter
baumannii.
We
untangled
unusual
mechanism
A
through
combination
bioinformatics,
site-directed
mutagenesis,
vitro
reconstitution,
molecular
modeling,
dynamics
simulation.
Our
findings
clarify
roles
NRPS
enzymes,
uncovering
catalytically
redundant
domains
identifying
multifunctional
nature
FbsF
cyclization
(Cy)
domain.
demonstrate
dynamic
interplay
between
l-serine
2,3-dihydroxybenzoic
acid
derived
dipeptides,
partitioning
amide
ester
forms
via
1,2-N-to-O-acyl
shift
orchestrated
noncanonical,
multichannel
Cy
The
event
occurs
secondary
condensation
facilitated
this
domain
two
dipeptidyl
intermediates,
which
generates
tetrapeptide
thioester.
Finally,
terminal
FbsG
recruits
soluble
nucleophile
release
final
product.
This
study
advances
understanding
intricate
biosynthetic
pathways
employed
NRPSs,
shedding
light
mechanisms
synthesis
peptides.
Journal of the American Chemical Society,
Год журнала:
2024,
Номер
146(19), С. 13399 - 13405
Опубликована: Май 3, 2024
Structural
motifs
containing
nitrogen-nitrogen
(N-N)
bonds
are
prevalent
in
a
large
number
of
clinical
drugs
and
bioactive
natural
products.
Hydrazine
(N
Journal of the American Chemical Society,
Год журнала:
2023,
Номер
145(49), С. 27131 - 27139
Опубликована: Ноя. 29, 2023
Azoxy
compounds
exhibit
a
wide
array
of
biological
activities
and
possess
distinctive
chemical
properties.
Although
there
has
been
considerable
interest
in
the
biosynthetic
mechanisms
azoxy
metabolites,
enzymatic
basis
responsible
for
bond
formation
remained
largely
enigmatic.
In
this
study,
we
unveil
enzyme
cascade
that
constructs
valanimycin
biosynthesis.
Our
research
demonstrates
pair
metalloenzymes,
comprising
membrane-bound
hydrazine
synthase
nonheme
diiron
synthase,
collaborate
to
convert
an
unstable
pathway
intermediate
product
through
hydrazine-azo-azoxy
pathway.
Additionally,
by
characterizing
homologues
from
other
metabolite
pathways,
propose
two-enzyme
could
represent
conserved
strategy
bacteria.
These
findings
provide
significant
mechanistic
insights
into
N–N
should
facilitate
targeted
isolation
bioactive
genome
mining.
Nitrogen-Nitrogen
(N-N)
bond-containing
functional
groups
in
natural
products
and
synthetic
drugs
play
significant
roles
exerting
biological
activities.
The
mechanisms
of
N-N
bond
formation
organic
molecules
have
garnered
increasing
attention
over
the
decades.
Recent
advances
illuminated
various
enzymatic
nonenzymatic
strategies,
our
understanding
construction
is
rapidly
expanding.
A
group
didomain
proteins
with
zinc-binding
cupin/methionyl-tRNA
synthetase
(MetRS)-like
domains,
also
known
as
hydrazine
synthetases,
generates
amino
acid-based
hydrazines,
which
serve
key
biosynthetic
precursors
diverse
functionalities
such
hydrazone,
diazo,
triazene,
pyrazole,
pyridazinone
groups.
In
this
review,
we
summarize
current
knowledge
on
pathways
employing
unique
bond-forming
machinery.
Cupin/methionyl-tRNA
synthetase
(MetRS)-like
didomain
enzymes
catalyze
nitrogen-nitrogen
(N-N)
bond
formation
between
Nω-hydroxylamines
and
amino
acids
to
generate
hydrazines,
key
biosynthetic
intermediates
of
various
natural
products
containing
N-N
bonds.
While
the
combination
these
two
building
blocks
leads
creation
diverse
hydrazine
products,
full
extent
their
structural
diversity
remains
largely
unknown.
To
explore
this,
we
herein
conducted
phylogeny-guided
genome-mining
related
pathways
consisting
enzymes:
flavin-dependent
Nω-hydroxylating
monooxygenases
(NMOs)
that
produce
Nω-hydroxylamine
precursors
cupin/MetRS-like
couple
with
via
A
phylogenetic
analysis
identified
unexplored
sequence
spaces
enzyme
families.
The
biochemical
characterization
NMOs
demonstrated
capabilities
Nω-hydroxylamines,
including
those
previously
not
known
as
Furthermore,
five
new
novel
combinations
blocks,
one
non-amino
acid
blocks:
1,3-diaminopropane
putrescine.
This
study
substantially
expanded
variety
forming
mediated
by
enzymes.
ACS Catalysis,
Год журнала:
2024,
Номер
15(1), С. 310 - 342
Опубликована: Дек. 17, 2024
The
biological
formation
of
nitrogen–nitrogen
(N–N)
bonds
represents
intriguing
reactions
that
have
attracted
much
attention
in
the
past
decade.
This
interest
has
led
to
an
increasing
number
N–N
bond-containing
natural
products
(NPs)
and
related
enzymes
catalyze
their
(referred
this
review
as
NNzymes)
being
elucidated
studied
greater
detail.
While
more
detailed
information
on
biosynthesis
NPs,
which
only
become
available
recent
years,
provides
unprecedented
source
biosynthetic
enzymes,
potential
for
biocatalytic
applications
been
minimally
explored.
With
review,
we
aim
not
provide
a
comprehensive
overview
both
characterized
NNzymes
hypothetical
biocatalysts
with
putative
bond
forming
activity,
but
also
highlight
from
perspective.
We
present
compare
conventional
synthetic
approaches
linear
cyclic
hydrazines,
hydrazides,
diazo-
nitroso-groups,
triazenes,
triazoles
allow
comparison
enzymatic
routes
via
these
functional
groups.
Moreover,
pathways
well
diversity
reaction
mechanisms
are
presented
according
direct
groups
currently
accessible
enzymes.
Journal of the American Chemical Society,
Год журнала:
2025,
Номер
unknown
Опубликована: Март 19, 2025
Formycin
A
and
pyrazofurin
are
two
naturally
occurring
pyrazole-derived
C-nucleosides
with
antibacterial
antiviral
activities.
While
earlier
studies
have
established
the
chemistry
of
C-glycosidic
bond
formation
as
well
subsequent
steps
in
biosynthesis
formycin
pyrazofurin,
how
pyrazole
ring
itself
is
constructed
remains
elusive.
N-N
was
previously
reported
to
involve
coupling
N6-hydroxylated
l-lysine
l-glutamic
acid
catalyzed
by
hydrazine
synthetase
PyfG,
herein
PyfG
its
homologue
ForJ
shown
instead
recognize
d-glutamate
l-glutamate.
The
product
ForJ/PyfG
catalysis
then
releases
α-hydrazino
d-glutamic
upon
processing
NAD-dependent
oxidoreductase
ForL.
Furthermore,
N-acylation
an
amino
ATP-grasp
ligase
ForM/PyfJ
indispensable
for
recognition
FAD-dependent
ForR/PyfK
perform
dehydrogenation
Cα-N
thereby
form
a
hydrazone
intermediate.
This
work
not
only
demonstrates
that
correct
substrate
but
also
reveals
cryptic
step
assembly
core.
These
results
thus
provide
significant
insights
into
rings
rarely
seen
natural
products.
Angewandte Chemie International Edition,
Год журнала:
2023,
Номер
63(1)
Опубликована: Ноя. 15, 2023
Valanimycin
is
an
azoxy-containing
natural
product
isolated
from
the
fermentation
broth
of
Streptomyces
viridifaciens
MG456-hF10.
While
biosynthesis
valanimycin
has
been
partially
characterized,
how
azoxy
group
constructed
remains
obscure.
Herein,
membrane
protein
VlmO
and
putative
hydrazine
synthetase
ForJ
formycin
biosynthetic
pathway
are
demonstrated
to
catalyze
N-N
bond
formation
converting
O-(l-seryl)-isobutyl
hydroxylamine
into
N-(isobutylamino)-l-serine.
Subsequent
installation
shown
be
catalyzed
by
non-heme
diiron
enzyme
VlmB
in
a
reaction
which
single
VlmO/ForJ
oxidized
four
electrons
yield
group.
The
catalytic
cycle
appears
begin
with
resting
μ-oxo
diferric
complex
VlmB,
as
supported
Mössbauer
spectroscopy.
This
study
also
identifies
N-(isobutylamino)-d-serine
alternative
substrate
for
leading
two
regioisomers.
reactions
kinase
VlmJ
lyase
VlmK
during
final
steps
established
well.
was
thus
fully
reconstituted
vitro
using
enzymes
VlmO/ForJ,
VlmK.
Importantly,
VlmB-catalyzed
represents
first
example
enzyme-catalyzed
expected
proceed
atypical
mechanism.
Abstract
The
diazo
group
is
an
important
functional
in
organic
synthesis
because
it
confers
high
reactivity
to
the
compounds
and
has
been
applied
various
chemical
reactions,
such
as
Sandmeyer
reaction,
Wolff
rearrangement,
cyclopropanation,
C−N
bond
formation
with
active
methylene
compounds.
Previously,
we
revealed
that
3‐diazoavenalumic
acid
(3‐DAA),
which
potentially
produced
by
several
actinomycete
species
contains
aromatic
group,
a
biosynthetic
intermediate
of
avenalumic
acid.
In
this
study,
aimed
construct
production
system
for
phenyldiazene
derivatives
adding
culture
3‐DAA‐producing
recombinant
actinomycete.
First,
acetoacetanilide
its
derivatives,
have
are
raw
materials
arylide
yellow
dyes,
were
individually
added
When
their
metabolites
analyzed,
each
expected
compound
phenyldiazenyl
moiety
was
detected
extract.
Moreover,
established
one‐pot
vitro
enzymatic
same
using
highly
reactive
diazotase,
CmaA6.
These
results
showed
natural
products
attractive
tool
expanding
structural
diversity
both
vivo
.
Natural Product Reports,
Год журнала:
2023,
Номер
40(8), С. 1298 - 1302
Опубликована: Янв. 1, 2023
A
personal
selection
of
32
recent
papers
is
presented,
covering
various
aspects
current
developments
in
bioorganic
chemistry
and
novel
natural
products,
such
as
clavirolide
L
from
Clavularia
viridis
.
