Anaerobic and aerobic degradation of cyanophycin by the denitrifying bacterium Pseudomonas alcaligenes strain DIP1 and role of three other coisolates in a mixed bacterial consortium

Cyanophycin and its biosynthesis: not hot but very cool

Covering: 1878 to early 2023Cyanophycin is a biopolymer consisting of a poly-aspartate backbone with arginines linked to each Asp sidechain through isopeptide bonds. Cyanophycin is made by cyanophycin synthetase 1 or 2 through ATP-dependent polymerization of Asp and Arg, or β-Asp-Arg, respectively. It is degraded into dipeptides by exo-cyanophycinases, and these dipeptides are hydrolyzed into free amino acids by general or dedicated isodipeptidase enzymes. When synthesized, chains of cyanophycin coalesce into large, inert, membrane-less granules. Although discovered in cyanobacteria, cyanophycin is made by species throughout the bacterial kingdom, and cyanophycin metabolism provides advantages for toxic bloom forming algae and some human pathogens. Some bacteria have developed dedicated schemes for cyanophycin accumulation and use, which include fine temporal and spatial regulation. Cyanophycin has also been heterologously produced in a variety of host organisms to a remarkable level, over 50% of the host's dry mass, and has potential for a variety of green industrial applications. In this review, we summarize the progression of cyanophycin research, with an emphasis on recent structural studies of enzymes in the cyanophycin biosynthetic pathway. These include several unexpected revelations that show cyanophycin synthetase to be a very cool, multi-functional macromolecular machine.

Bioinformatics of cyanophycin metabolism genes and characterization of promiscuous isoaspartyl dipeptidases that catalyze the final step of cyanophycin degradation

Cyanophycin is a bacterial biopolymer used for storage of fixed nitrogen. It is composed of a backbone of L-aspartate residues with L-arginines attached to each of their side chains. Cyanophycin is produced by cyanophycin synthetase 1 (CphA1) using Arg, Asp and ATP, and is degraded in two steps. First, cyanophycinase breaks down the backbone peptide bonds, releasing β-Asp-Arg dipeptides. Then, these dipeptides are broken down into free Asp and Arg by enzymes with isoaspartyl dipeptidase activity. Two bacterial enzymes are known to possess promiscuous isoaspartyl dipeptidase activity: isoaspartyl dipeptidase (IadA) and isoaspartyl aminopeptidase (IaaA). We performed a bioinformatic analysis to investigate whether genes for cyanophycin metabolism enzymes cluster together or are spread around the microbial genomes. Many genomes showed incomplete contingents of known cyanophycin metabolizing genes, with different patterns in various bacterial clades. Cyanophycin synthetase and cyanophycinase are usually clustered together when recognizable genes for each are found within a genome. Cyanophycinase and isoaspartyl dipeptidase genes typically cluster within genomes lacking cphA1. About one-third of genomes with genes for CphA1, cyanophycinase and IaaA show these genes clustered together, while the proportion is around one-sixth for CphA1, cyanophycinase and IadA. We used X-ray crystallography and biochemical studies to characterize an IadA and an IaaA from two such clusters, in Leucothrix mucor and Roseivivax halodurans, respectively. The enzymes retained their promiscuous nature, showing that being associated with cyanophycin-related genes did not make them specific for β-Asp-Arg dipeptides derived from cyanophycin degradation.

Discovery of cyanophycin dipeptide hydrolase enzymes suggests widespread utility of the natural biopolymer cyanophycin

Cyanophycin is a bacterial polymer mainly used for nitrogen storage. It is composed of a peptide backbone of L-aspartate residues with L-arginines attached to their side chains through isopeptide bonds. Cyanophycin is degraded in two steps: Cyanophycinase cleaves the polymer into β-Asp-Arg dipeptides, which are hydrolyzed into free Asp and Arg by enzymes possessing isoaspartyl dipeptide hydrolase activity. Two unrelated enzymes with this activity, isoaspartyl dipeptidase (IadA) and isoaspartyl aminopeptidase (IaaA) have been shown to degrade β-Asp-Arg dipeptides, but bacteria which encode cyanophycin-metabolizing genes can lack iaaA and iadA genes. In this study, we investigate a previously uncharacterized enzyme whose gene can cluster with cyanophycin-metabolizing genes. This enzyme, which we name cyanophycin dipeptide hydrolase (CphZ), is specific for dipeptides derived from cyanophycin degradation. Accordingly, a co-complex structure of CphZ and β-Asp-Arg shows that CphZ, unlike IadA or IaaA, recognizes all portions of its β-Asp-Arg substrate. Bioinformatic analyses showed that CphZ is found in very many proteobacteria and is homologous to an uncharacterized protein encoded in the "arginine/ornithine transport" (aot) operon of many pseudomonas species, including Pseudomonas aeruginosa. In vitro assays show that AotO is indeed a CphZ, and in cellulo growth experiments show that this enzyme and the aot operon allow P. aeruginosa to take up and use β-Asp-Arg as a sole carbon and nitrogen source. Together the results establish the novel, highly specific enzyme subfamily of CphZs, suggesting that cyanophycin is potentially used by a much wider range of bacteria than previously appreciated.

The structure of cyanophycinase in complex with a cyanophycin degradation intermediate

BACKGROUND

Cyanophycinases are serine protease family enzymes which are required for the metabolism of cyanophycin, the natural polymer multi-L-arginyl-poly(L-aspartic acid). Cyanophycinases degrade cyanophycin to β-Asp-Arg dipeptides, which enables use of this important store of fixed nitrogen.

METHODS

We used genetic code expansion to incorporate diaminopropionic acid into cyanophycinase in place of the active site serine, and determined a high-resolution structure of the covalent acyl-enzyme intermediate resulting from attack of cyanophycinase on a short cyanophycin segment.

RESULTS

The structure indicates that cyanophycin dipeptide residues P1 and P1' bind shallow pockets adjacent to the catalytic residues. We observe many cyanophycinase - P1 dipeptide interactions in the co-complex structure. Calorimetry measurements show that at least two cyanophycin dipeptides are needed for high affinity binding to cyanophycinase. We also characterized a putative cyanophycinase which we found to be structurally very similar but that shows no activity and could not be activated by mutation of its active site.

GENERAL SIGNIFICANCE

Despite its peptidic structure, cyanophycin is resistant to degradation by peptidases and other proteases. Our results help show how cyanophycinase can specifically bind and degrade this important polymer.

Characterization of an efficient extracellular cyanophycinase and its encoding cphEStrept. gene from Streptomyces pratensis strain YSM

Until now, no enzymes were described that hydrolyze cyanophycin granular protein (CGP) from a species of the genus Streptomyces. An isolate able to hydrolyze CGP was identified as Streptomyces pratensis strain YSM. The CGPase from S. pratensis strain YSM had an optimum activity at 42 °C and pH 8.5, and was able to degrade CGP at a rate of 12 ± 0.3 μg/mL min. Additionally, this CGPase hydrolyzes water-soluble CGP significantly faster than water-insoluble CGP. The molecular mass of CGPase subunits from S. pratensis strain YSM as determined by SDS-PAGE was about 43 kDa, and the enzyme was entirely inhibited by serine-protease inhibitors. The CGPase coding gene (cphE_Strept.) was amplified from genomic DNA using primers designed form consensus sequence of putative CGPase sequences. The cphE_Strept. was 1427 bp encoding a CGPase of 420 amino acids that showed about 44% and 22% similarities to CGPase from Pseudomonas anguilliseptica BI and Synechocystis sp. PCC 6803, respectively. The catalytic triad and serine-protease residues (GXSXG) were identified in the CphE_Strept. sequence. Dipeptides and tetrapeptides were identified as hydrolysis products. Biotechnological exploitation of S. pratensis strain YSM for CGPase production might have an advantage due to the reduction of separation costs and its ability to degrade CGP in phosphate buffer saline using actively growing or resting cells.

Strategy for the Biosynthesis of Short Oligopeptides: Green and Sustainable Chemistry

Short oligopeptides are some of the most promising and functionally important amide bond-containing components, with widespread applications. Biosynthesis of these oligopeptides may potentially become the ultimate strategy because it has better cost efficiency and environmental-friendliness than conventional solid phase peptide synthesis and chemo-enzymatic synthesis. To successfully apply this strategy for the biosynthesis of structurally diverse amide bond-containing components, the identification and selection of specific biocatalysts is extremely important. Given that perspective, this review focuses on the current knowledge about the typical enzymes that might be potentially used for the synthesis of short oligopeptides. Moreover, novel enzymatic methods of producing desired peptides via metabolic engineering are highlighted. It is believed that this review will be helpful for technological innovation in the production of desired peptides.

Features of the biotechnologically relevant polyamide family "cyanophycins" and their biosynthesis in prokaryotes and eukaryotes

Cyanophycin, inclusions in cyanobacteria discovered by the Italian scientist Borzi in 1887, were characterized as a polyamide consisting of aspartic acid and arginine. Its synthesis in cyanobacteria was analyzed regarding growth conditions, responsible gene product, requirements, polymer structure and properties. Heterologous expression of diverse cyanophycin synthetases (CphA) in Escherichia coli enabled further enzyme characterization. Cyanophycin is a polyamide with variable composition and physiochemical properties dependent on host and cultivation conditions in contrast to the extracellular polyamides poly-γ-glutamic acid and poly-ε-l-lysine. Furthermore, recombinant prokaryotes and transgenic eukaryotes, including plants expressing different cphA genes, were characterized as suitable for production of insoluble cyanophycin regarding higher yields and modified composition for other requirements and applications. In addition, cyanophycin was characterized as a source for the synthesis of polyaspartic acid or N-containing bulk chemicals and dipeptides upon chemical treatment or degradation by cyanophycinases, respectively. Moreover, water-soluble cyanophycin derivatives with altered amino acid composition were isolated from transgenic plants, yeasts and recombinant bacteria. Thereby, the range of dipeptides could be extended by biological processes and by chemical modification, thus increasing the range of applications for cyanophycin and its dipeptides, including agriculture, food supplementations, medical and cosmetic purposes, synthesis of the polyacrylate substitute poly(aspartic acid) and other applications.

Increased lysine content is the main characteristic of the soluble form of the polyamide cyanophycin synthesized by recombinant Escherichia coli

Cyanophycin, a polyamide of cyanobacterial or noncyanobacterial origin consisting of aspartate, arginine, and lysine, was synthesized in different recombinant strains of Escherichia coli expressing cphA from Synechocystis sp. strain PCC 6308 or PCC 6803, Anabaena sp. strain PCC 7120, or Acinetobacter calcoaceticus ADP1. The molar aspartate/arginine/lysine ratio of the water-soluble form isolated from a recombinant strain expressing CphA6308 was 1:0.5:0.5, with a lysine content higher than any ever described before. The water-insoluble form consisted instead of mainly aspartate and arginine residues and had a lower proportion of lysine, amounting to a maximum of only 5 mol%. It could be confirmed that the synthesis of soluble cyanobacterial granule polypeptide (CGP) is independent of the origin of cphA. Soluble CGP isolated from all recombinant strains contained a least 17 mol% lysine. The total CGP portion of cell dry matter synthesized by CphA6308 from recombinant E. coli was about 30% (wt/wt), including 23% (wt/wt) soluble CGP, by using terrific broth complex medium for cultivation at 30°C for 72 h. Enhanced production of soluble CGP instead of its insoluble form is interesting for further application and makes recombinant E. coli more attractive as a suitable source for the production of polyaspartic acid or dipeptides. In addition, a new low-cost, time-saving, effective, and common isolation procedure for mainly soluble CGP, suitable for large-scale application, was established in this study.

Investigations on three genes in Ralstonia eutropha H16 encoding putative cyanophycin metabolizing enzymes

The genome sequence of the facultative chemolithoautotrophic bacterium Ralstonia eutropha H16 exhibited two coding sequences with high homologies to cyanophycin synthetases (CphA) as well as one gene coding for a putative cyanophycinase (CphB). To investigate whether or not the genes cphA H16 (H16_A0774), cphA'H16 (H16_A0775) and cphB H16 (H16_B1013) encode active cyanophycin (CGP) metabolism proteins, several functional analyses were performed. Extensive in silico analysis revealed that all characteristic motifs are conserved within CphAH16, whereas CphA'H16 misses a large part of the so-called J-loop present in other active cyanophycin synthetases. Although transcription of both genes was demonstrated by RT-PCR, and heterologously expressed cphA genes led to light-scattering inclusions in recombinant cells of Escherichia coli, no CGP could be isolated from the cells or detected by HPLC analysis. For all enzyme assay experiments carried out, significant enzyme activities were determined for CphA and CphA' in recombinant E. coli cells if crude cell extracts were applied. Homologous expression of cphA genes in cells of R. eutropha H16∆phaC1 did not result in the formation of light-scattering inclusions, and no CGP could be isolated from the cells or detected by HPLC analysis. No transcription of cphB encoding a putative cyanophycinase could be detected by RT-PCR analysis and no overexpression was achieved in several strains of E. coli. Furthermore, no enzyme activity was detected by using CGP overlay agar plates.

Production optimization of cyanophycinase ChpEal from Pseudomonas alcaligenes DIP1

Pseudomonas alcaligenes DIP1 produces an extracellular cyanophycinase (CphE_al). The corresponding gene (cphE_al) was identified from subclones of a genomic DNA gene library by heterologously expressing the functionally active enzyme in Escherichia coli. The nucleotide sequence of the gene (1260 base pairs) was determined indicating a theoretical mass of 43.6 kDa (mature CphE_al) plus a leader peptide of 2,6 kDa which corresponds well to the apparent molecular mass of 45 kDa as revealed by SDS-PAGE. The enzyme exhibited a high sequence identity of 91% with the extracellular cyanophycinase from P. anguilliseptica strain BI and carried an N-terminal Sec secretion signal peptide. Analysis of the amino acid sequence of cphE revealed a putative catalytic triad consisting of the serine motif GXSXG plus a histidine and a glutamate residue, suggesting a catalytic mechanism similar to serine-type proteases. The cyanophycinase (CphE_al) was heterologously produced in two different E. coli strains (Top10 and BL21(DE3)) from two plasmid vectors (pBBR1MCS-4 and pET-23a(+)). The signal peptide of CphE_al was cleaved in E. coli, suggesting active export of the protein at least to the periplasm. Substantial enzyme activity was also present in the culture supernatants. The extracellular cyanophycinase activities in E. coli were higher than activities in the wild type P. alcaligenes DIP1 in complex LB medium. Highest extracellular enzyme production was achieved with E. coli BL21(DE3) expressing CphE_al from pBBR1MCS-4. Using M9 minimal medium was less effective, but the relatively low cost of mineral salt media makes these results important for the industrial-scale production of dipeptides from cyanophycin.

Zobellella denitrificans strain MW1, a newly isolated bacterium suitable for poly(3-hydroxybutyrate) production from glycerol

AIMS

To search for new bacteria for efficient production of polyhydroxyalkanoates (PHAs) from glycerol.

METHODS AND RESULTS

Samples were taken from different environments in Germany and Egypt, and bacteria capable of growing in mineral salts medium with glycerol as sole carbon source were enriched. From a wastewater sediment sample in Egypt, a Gram-negative bacterium (strain MW1) was isolated that exhibited good growth and that accumulated considerable amounts of polyhydroxybutyrate (PHB) from glycerol and also from other carbon sources. The 16S rRNA gene sequence of this isolate exhibited 98.5% and 96.2% similarity to Zobellella denitrificans strain ZD1 and to Zobellella taiwanensis strain ZT1 respectively. The isolate was therefore affiliated as strain MW1 of Z. denitrificans. Strain MW1 grows optimally on glycerol at 41 degrees C and pH 7.3 and accumulated PHB up to 80.4% (w/w) of cell dry weight. PHB accumulation was growth-associated. Although it was not an absolute requirement, 20 g l(-1) sodium chloride enhanced both growth (5 g cell dry weight per litre) and PHB content (87%, w/w). Zobellella denitrificans strain MW1 is also capable to accumulate the poly(3-hydroxybutyrate-co-3-hydroxyvalerate) copolymer if sodium propionate was used as cosubstrate in addition to glycerol.

CONCLUSIONS

A new PHB-accumulating strain was isolated and identified. This strain is able to utilize glycerol for growth and PHB accumulation to high content especially in the presence of NaCl that will enable the utilization of waste glycerol from biodiesel industry.

SIGNIFICANCE AND IMPACT OF THE STUDY

This study is the first report on accumulation of PHA in a member of the new genus Zobellella. Furthermore, utilization of glycerol as the sole carbon source for fast growth and PHB biosynthesis, growth in the presence of NaCl and high PHB contents of the cells will make this newly isolated bacterium a potent candidate for industrial production of PHB from crude glycerol occurring as byproduct during biodiesel production.

Establishment of a novel anabolism-based addiction system with an artificially introduced mevalonate pathway: complete stabilization of plasmids as universal application in white biotechnology

Plasmid stability in recombinant microorganisms is a very important requirement for highly efficient plasmid-based production processes in biotechnology. To stably maintain plasmids, we developed in this study an efficient and stringent novel anabolism-based addiction system, which can be widely used. This novel addiction system is based on two components: (i) an Escherichia coli HMS174(DE3) knockout mutant of the ispH gene coding for 4-hydroxy-3-methylbut-2-enyl diphosphate reductase (EC 1.17.1.2) of the deoxyxylulose 5-phosphate (DXP) pathway, impairing the synthesis of isopentenyl pyrophosphate (IPP) and (ii) a completely synthetic and episomal mevalonate (MVA) pathway as an alternative supplier of essential IPP. The latter is encoded by a plasmid that contains the genes for HMG-CoA reductases from Lactococcus lactis and Staphylococcus aureus plus HMG-CoA-synthase, MVA kinase, MVP kinase and MVPP decarboxylase from S. aureus. This plasmid should then also harbor the genes for the protein or for the pathway that will be produced or that will be utilized for production of a chemical. To demonstrate the functionality of this addiction system, a mutated cyanophycin synthetase gene (cphA(6308)C595S) was used. To determine plasmid stabilities, flasks experiments in media supplied or not supplied with antibiotics were carried out with the knockout mutant and two control strains, one harboring plasmid pCOLADuet-1::MVA1-5::cphA(6308) and the other harboring a conventional expression plasmid pET-23a::cphA(6308). As revealed by measuring the colony-forming units of aliquots spread on solid media with or without antibiotics, the knockout mutant revealed a plasmid stability of 100% whereas the control strains exhibited plasmid stabilities of only 64% and 2%, respectively. Radiometric enzyme activity measurements for CphA revealed only 95% and 12.5% of the activity in the control strains harboring pCOLADuet-1::MVA1-5::cphA(6308) and pET-23a::cphA(6308), respectively, in comparison to the activity measured in the knockout mutant. The knockout mutant synthesized 9.5% (w/w of cell dry weight (CDW)) of cyanophycin, and the control strain harboring pCOLADuet-1::MVA1-5::cphA(6308) synthesized 13.6% (w/w of CDW) after growth without antibiotics.

Biotechnological process for production of beta-dipeptides from cyanophycin on a technical scale and its optimization

A triphasic process was developed for the production of beta dipeptides from cyanophycin (CGP) on a large scale. Phase I comprises an optimized acid extraction method for technical isolation of CGP from biomass. It yielded highly purified CGP consisting of aspartate, arginine, and a little lysine. Phase II comprises the fermentative production of an extracellular CGPase (CphE(al)) from Pseudomonas alcaligenes strain DIP1 on a 500-liter scale in mineral salts medium, with citrate as the sole carbon source and CGP as an inductor. During optimization, it was shown that 2 g liter(-1) citrate, pH 6.5, and 37 degrees C are ideal parameters for CphE(al) production. Maximum enzyme yields were obtained after induction in the presence of 50 mg liter(-1) CGP or CGP dipeptides for 5 or 3 h, respectively. Aspartate at a concentration of 4 g liter(-1) induced CphE(al) production with only about 30% efficiency in comparison to that with CGP. CphE(al) was purified utilizing its affinity for the substrate and its specific binding to CGP. CphE(al) turned out to be a serine protease with maximum activity at 50 degrees C and at pH 7 to 8.5. Phase III comprises degradation of CGP to beta-aspartate-arginine and beta-aspartate-lysine dipeptides with a purity of over 99% (by thin-layer chromatography and high-performance liquid chromatography), employing a crude CphE(al) preparation. Optimum degradation parameters were 100 g liter(-1) CGP, 10 g liter(-1) crude CphE(al) powder, and 4 h of incubation at 50 degrees C. The overall efficiency of phase III was 91%, while 78% (wt/wt) of the used CphE(al) powder with sustained activity toward CGP was recovered. The optimized process was performed with industrial materials and equipment and is applicable to any desired scale.