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Journal of Bacteriology, August 2004, p . 5187-5188, Vol . 186,
No . 16
Identification of a Key Step in the Biosynthetic Pathway of Bacteriochlorophyll
c and Its Implications for Other Known and Unknown Green Sulfur Bacteria
Robert E . Blankenship*
Department of Chemistry and Biochemistry, Arizona State University, Tempe,
Arizona 85287-1604
The enzyme responsible for the methylation at the C-20 methine
position of the bacteriochlorophylls c and e found in green
sulfur photosynthetic bacteria has been identified by genomics
and knockout mutagenesis . The distribution of this enzyme in other
green sulfur bacteria is surprising .
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ULTRAWEAK LIGHT COLLECTION BY GREEN PHOTOSYNTHETIC
BACTERIAL ANTENNAS |
The green photosynthetic bacteria are the world champions of doing
photosynthesis at low light intensities (7) . They accomplish
this by using a unique antenna complex known as a chlorosome,
which is packed with specialized photopigments, bacteriochlorophylls
c, d, and e (1) . These unusual
chlorophylls are not found in any other organisms, and they
self-assemble into large pigment oligomers with almost no involvement
of protein . This biosynthetically "cheap" antenna complex has an
enormous absorption cross-section and permits certain of these
organisms to live at the lowest light intensities known to support
photosynthesis, up to a million times lower light than normal
sunlight (8) . At these low intensities, each
bacteriochlorophyll absorbs a photon approximately once every 8 h! A
key step in the biosynthesis of bacteriochlorophylls c and
e (but not d) is the methylation at the C-20 position of
the chlorin macrocycle (Fig . 1) . The enzyme that carries
out this methylation (BchU) has previously not been identified .
However, in a recently published paper, Maresca et al . (4)
identify the methyltransferase enzyme in Chlorobium tepidum by
using a combination of comparative genomics and knockout mutagenesis .
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FIG . 1 . Chemical structures of bacteriochlorophylls c, d,
e, and f . The structural features that differentiate these
four pigments are circled . The C-20 methine position (solid circle) is
methyl in bacteriochlorophylls c and e and hydrogen in
bacteriochlorophylls d and f. The C-7 position (dashed
circle) is methyl in bacteriochlorophylls c and d and
formyl in bacteriochlorophylls e and f. R1 can
be ethyl, n-propyl, iso-butyl, or neo-pentyl; R2
is methyl or ethyl; and R3 is, in most cases, farnesyl.
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The investigators did some clever detective work to identify the gene
that codes for the C-20 methyltransferase . The complete Chlorobium
tepidum genome sequence has been determined (3),
but the genome contains many potential methyltransferase genes
and initial guesses were not correct . The identification was made by
comparative genomics with the filamentous anoxygenic phototrophic
(FAP) bacteria, also often called the green nonsulfur bacteria . These
organisms are the only other major group of bacteria that contain the
chlorosome antenna complex, although overall they are not close
relatives of the green sulfur bacteria, and a draft genome is
available for one member of this group, Chloroflexus aurantiacus .
Fortunately, genes that code for chlorosome components are clustered
in the FAP bacteria, while they are not in the green sulfur bacteria,
and this clustering suggested a methyltransferase gene as a good
candidate for the C-20 methylase . A knockout mutation in
Chlorobium tepidum had the expected phenotype of containing
bacteriochlorophyll d, which lacks the C-20 methyl group,
instead of bacteriochlorophyll c . This established the
identity of the gene, which was named bchU (4) .
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A SURPRISE FINDING AND SOME PREDICTIONS
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Other groups of green photosynthetic bacteria contain functional
chlorosomes that contain only bacteriochlorophyll d . Maresca
et al . (4) examined some of these strains . A surprise in their
findings is that at least one "wild-type" bacteriochlorophyll
d-containing organism also contains a bchU gene, but with a
frameshift mutation that leads to premature termination and an
inactive enzyme . Certain bacteriochlorophyll d-containing
strains have long been known to be prone to reversion to making
bacteriochlorophyll c when grown for extended periods at low
light intensities (2) . In some of these strains, Maresca et
al . (4) found that a second mutation restores the
original reading frame and results in an active methyltransferase
enzyme . Interesting questions remain about the observed distribution
of these bacteriochlorophyll d-containing organisms in nature
and how the C-20 methyl group affects the efficiency of light
collection . In laboratory growth competition experiments, Maresca et
al . (4) found that the bacteriochlorophyll d-containing
Chlorobium tepidum bchU mutant cells did not grow as rapidly
as the bacteriochlorophyll c-containing wild type under low
light conditions but grew at the same rate at higher light intensity .
Can it be that all bacteriochlorophyll d-containing strains
(which are often dominant isolates at somewhat higher positions in
the water column and therefore higher light intensities) really
contain a bchU gene that is inactivated by a frameshift and
susceptible to reversion? This seems unlikely, but this question
could be easily resolved by analysis of a series of
bacteriochlorophyll d-containing strains . It may be that some
of the common laboratory bacteriochlorophyll d-containing strains
have arisen in the laboratory by selective pressure due to culturing
at higher light intensities and that newly isolated bacteriochlorophyll
d-containing strains will lack the gene entirely .
There is one additional pigment in the series of pigments that
comprise the chlorobium chlorophylls, bacteriochlorophyll f
(Fig . 1) . This pigment has never been observed in nature, but
it is the logical final member of this series of pigments, in
that it contains hydrogen at C-20 and formyl at C-7 . According to the
progression of in vivo absorption maxima, in which bacteriochlorophyll
c typically absorbs at 750 to 760 nm, bacteriochlorophyll d
at 725 to 735 nm, and bacteriochlorophyll e at 710 to 720 nm,
bacteriochlorophyll f should absorb at about 690 to 710 nm .
It is a bit of a mystery why bacteriochlorophyll f-containing
organisms have never been found, as both of the enzymes that
make the two functional groups are clearly present in closely related
species . The predicted 690- to 710-nm spectral window would appear to
be a niche that is not well exploited, as it is just to the red of
the chlorophyll a absorption band that is usually dominant .
The only other known organisms that absorb in this spectral region
are the chlorophyll d-containing cyanobacteria, which are not
widely distributed (5) .
It should be possible to produce an organism that contains
bacteriochlorophyll f, simply by knocking out the C-20
methyltransferase enzyme in a bacteriochlorophyll e-containing
strain . While none of the bacteriochlorophyll e-containing
strains have genetic systems yet available, this should still be
relatively straightforward .
A final puzzle yet to be solved is the identification of the
enzyme that makes the formyl group at the C-7 position in bacteriochlorophyll
e . This is the same position and functional group that is found
in chlorophyll b . However, the enzymes are almost certainly
not homologous, as the enzyme that makes chlorophyll b is a
mixed-function oxidase that relies on O2 as a substrate (9)
and the bacteriochlorophyll e-containing bacteria are strict
anaerobes . This is almost certainly another in a growing group
of cases of gene replacement, in which the same biosynthetic steps
are carried out by entirely different enzymes in anaerobic and
aerobic organisms, with only the aerobic enzymes using O2
as a substrate . Other examples include the coproporphyrinogen oxidase
involved in heme and chlorophyll biosynthesis (HemN versus HemF), the
oxidative cyclase that makes the isocyclic ring in chlorophylls (BchE
versus AcsF), and ribonucleotide reductase (NrdG versus NrdB) (6) .
The anaerobic versions are probably the more ancient enzymes, dating
to a time more than 2.2 billion years ago when the earth was largely
anaerobic, and the more efficient aerobic versions that use the
powerful oxidant O2 have replaced the older ones whenever
possible .
* Mailing address: Department of Chemistry and Biochemistry,
Arizona State University, Tempe, AZ 85287-1604 . Phone: (480) 965-4430 . Fax:
(480) 965-2747 . E-mail: Blankenship@asu.edu.
The views expressed in this Commentary do not necessarily
reflect the views of the journal or of ASM.
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Chlorobium tepidum encodes the C-20 methyltransferase in
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