Phytochromes are biological photoswitches
that interconvert between
two parent states (Pr and Pfr). The transformation is initiated by
photoisomerization of the tetrapyrrole chromophore, followed by a
sequence of chromophore and protein structural changes. In the last
step, a phytochrome-specific peptide segment (tongue) undergoes a
secondary structure change, which in prokaryotic phytochromes is associated
with the (de)activation of the output module. The focus of this work
is the Pfr-to-Pr photoconversion of the bathy bacteriophytochrome
Agp2 in which Pfr is the thermodynamically stable state. Using spectroscopic
techniques, we studied the structural and functional consequences
of substituting Arg211, Tyr165, His278, and Phe192 close to the biliverdin
(BV) chromophore. In Pfr, substitutions of these residues do not affect
the BV structure. The characteristic Pfr properties of bathy phytochromes,
including the protonated propionic side chain of ring C (propC) of
BV, are preserved. However, replacing Arg211 or Tyr165 blocks the
photoconversion in the Meta-F state, prior to the secondary structure
transition of the tongue and without deprotonation of propC. The Meta-F
state of these variants displays low photochemical activity, but electronic
excitation causes ultrafast alterations of the hydrogen bond network
surrounding the chromophore. In all variants studied here, thermal
back conversion from the photoproducts to Pfr is decelerated but substitution
of His278 or Phe192 is not critical for the Pfr-to-Pr photoconversion.
These variants do not impair deprotonation of propC or the α-helix/β-sheet
transformation of the tongue during the Meta-F-to-Pr decay. Thus,
we conclude that propC deprotonation is essential for restructuring
of the tongue.
Methane is a promising next-generation carbon feedstock for industrial biotechnology due to its low price and huge availability. Biological conversion of methane to valuable products can mitigate methane-induced global warming as greenhouse gas. There have been challenges for the conversion of methane into various chemicals and fuels using engineered non-native hosts with synthetic methanotrophy or methanotrophs with the reconstruction of synthetic pathways for target products. Herein, we analyze the technical challenges and issues of potent methane bioconversion technology. Pros and cons of metabolic engineering of methanotrophs for methane bioconversion, and perspectives on the bioconversion of methane to chemicals and liquid fuels are discussed.
Bacteriophytochromes
harboring a biliverdin IXα (BV) chromophore
undergo photoinduced reaction cascades to switch between physiologically
inactive and active states. Employing vibrational spectroscopic and
computational methods, we analyzed the role of propionic substituents
of BV in the transformations between parent states Pr and Pfr in prototypical
(Agp1) and bathy (Agp2) phytochromes from Agrobacterium fabrum. Both proteins form adducts with BV monoesters (BVM), esterified
at propionic side chain B (PsB)
or C (PsC), but in each case, only
one monoester adduct is reactive. In the reactive Agp2-BVM-B complex (esterified at ring B), the Pfr
dark state displays the structural properties characteristic of bathy
phytochromes, including a protonated PsC. As in native
Agp2, PsC is deprotonated in the final step of the
Pfr phototransformation. However, the concomitant α-helix/β-sheet
secondary structure change of the tongue is blocked at the stage of
unfolding of the coiled loop region. This finding and the shift of
the tautomeric equilibrium of BVM toward the enol form are attributed
to the drastic changes in the electrostatic potential. The calculations
further suggest that deprotonation of PsC and the
protonation state of His278 control the reactivity of the enol tautomer,
thereby accounting for the extraordinarily slow thermal reversion.
Although strong perturbations of the electrostatic potential are also
found for Agp1-BVM, the consequences for the Pr-to-Pfr phototransformation
are less severe. Specifically, the structural transition of the tongue
is not impaired and thermal reversion is even accelerated. The different
response of Agp1 and Agp2 to monoesterification of BV points to different
photoconversion mechanisms.
BackgroundMethanotrophs play an important role in biotechnological applications, with their ability to utilize single carbon (C1) feedstock such as methane and methanol to produce a range of high-value compounds. A newly isolated obligate methanotroph strain, Methylomonas sp. DH-1, became a platform strain for biotechnological applications because it has proven capable of producing chemicals, fuels, and secondary metabolites from methane and methanol. In this study, transcriptome analysis with RNA-seq was used to investigate the transcriptional change of Methylomonas sp. DH-1 on methane and methanol. This was done to improve knowledge about C1 assimilation and secondary metabolite pathways in this promising, but under-characterized, methane-bioconversion strain.ResultsWe integrated genomic and transcriptomic analysis of the newly isolated Methylomonas sp. DH-1 grown on methane and methanol. Detailed transcriptomic analysis indicated that (i) Methylomonas sp. DH-1 possesses the ribulose monophosphate (RuMP) cycle and the Embden–Meyerhof–Parnas (EMP) pathway, which can serve as main pathways for C1 assimilation, (ii) the existence and the expression of a complete serine cycle and a complete tricarboxylic acid (TCA) cycle might contribute to methane conversion and energy production, and (iii) the highly active endogenous plasmid pDH1 may code for essential metabolic processes. Comparative transcriptomic analysis on methane and methanol as a sole carbon source revealed different transcriptional responses of Methylomonas sp. DH-1, especially in C1 assimilation, secondary metabolite pathways, and oxidative stress. Especially, these results suggest a shift of central metabolism when substrate changed from methane to methanol in which formaldehyde oxidation pathway and serine cycle carried more flux to produce acetyl-coA and NADH. Meanwhile, downregulation of TCA cycle when grown on methanol may suggest a shift of its main function is to provide de novo biosynthesis, but not produce NADH.ConclusionsThis study provides insights into the transcriptomic profile of Methylomonas sp. DH-1 grown on major carbon sources for C1 assimilation, providing in-depth knowledge on the metabolic pathways of this strain. These observations and analyses can contribute to future metabolic engineering with the newly isolated, yet under-characterized, Methylomonas sp. DH-1 to enhance its biochemical application in relevant industries.Electronic supplementary materialThe online version of this article (10.1186/s12864-019-5487-6) contains supplementary material, which is available to authorized users.
Methylomonas sp. DH-1, newly isolated from the activated sludge of a brewery plant, has been used as a promising biocatalytic platform for the conversion of methane to value-added chemicals. Methylomonas sp. DH-1 can efficiently convert methane and propane into methanol and acetone with a specific productivity of 4.31 and 0.14 mmol/g cell/h, the highest values ever reported, respectively. Here, we present the complete genome sequence of Methylomonas sp. DH-1 which consists of a 4.86 Mb chromosome and a 278 kb plasmid. The existence of a set of genes related to one-carbon metabolism and various secondary metabolite biosynthetic pathways including carotenoid pathways were identified. Interestingly, Methylomonas sp. DH-1 possesses not only the genes of the ribulose monophosphate cycle for type I methanotrophs but also the genes of the serine cycle for type II. Methylomonas sp. DH-1 accumulated 80 mM succinate from methane under aerobic conditions, because DH-1 has 2-oxoglutarate dehydrogenase activity and the ability to operate the full TCA cycle. Availability of the complete genome sequence of Methylomonas sp. DH-1 enables further investigations on the metabolic engineering of this strain for the production of value-added chemicals from methane.
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