Biosynthesis and Characterization of Polyhydroxyalkanoates with

Publication Date (Web): January 23, 2018 ... H. mediterranei is ideal for large-scale production of PHBV due to its inherent bioprocessing advantages,...
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Biosynthesis and Characterisation of Polyhydroxyalkanoates with Controlled Composition and Microstructure Anna Ferre-Guell, and James Winterburn Biomacromolecules, Just Accepted Manuscript • DOI: 10.1021/acs.biomac.7b01788 • Publication Date (Web): 23 Jan 2018 Downloaded from http://pubs.acs.org on January 24, 2018

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Biomacromolecules

1

Biosynthesis and Characterisation of

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Polyhydroxyalkanoates with Controlled

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Composition and Microstructure

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Anna Ferre-Guell, James Winterburn*

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School of Chemical Engineering and Analytical Science, The Mill, The University of

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Manchester, Manchester M13 9PL, UK

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ABSTRACT

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Volatile fatty acids (VFA) C2:0 to C6:0 were used as a sole carbon source the production of

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poly(3-hydroxybutyrate-co-3-hydroxyvalerate)

(PHBV)

production

with

controllable

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composition and microstructure in Haloferax mediterranei. Feeding carbon-even VFA gave

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>90 mol% poly(3-hydroxybutyrate) (3HB) PHBV while carbon-odd VFA generated >87 mol%

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poly(3-hydroxyvalerate) (3HV) PHBV. Bespoke random, block and blend copolymers with

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0-100 mol% 3HV were synthesized using C4:0/C5:0 mixtures. The copolymer 3HV fraction is

14

proportional to the %C5:0 in the feed mixture, allowing control over composition.

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Microstructure depends on the substrate addition order: co-feeding generated random

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copolymers whilst sequential feeding created block and blend copolymers. On average the

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PHBV had an ultra-high molecular weight of 3×106 g/mol. 3HV rich PHBV showed lower

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melting temperature, enhanced elasticity and ductility. H. mediterranei is ideal for large-scale

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production of PHBV due to its inherent bioprocessing advantages. Control over the composition

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and microstructure of PHBV will facilitate the production of biopolymers capable of meeting

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industrial criteria for specific applications.

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KEYWORDS

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Halophile, Haloferax mediterranei, PHBV, block copolymer, volatile fatty acids (VFA),

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material properties

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INTRODUCTION

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Interest in the development of environmentally friendly alternatives to oil-based plastics is

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growing due to the problems associated with the processing and disposal of traditional plastics.

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Biopolymers such as polyhydroxyalkanoates (PHA) have attracted considerable attention as

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potential candidates to replace some oil-based plastics because of their biodegradability,

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biocompatibility and similarity in terms of mechanical properties. PHA have the added benefit of

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being produced from renewable resources and thus being independent of crude oil price and

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availability1,2.

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PHAs are a family of natural polyesters that accumulates inside different bacteria and archaea

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as intracellular granules acting as a carbon and energy reservoir. More than 150 different types of

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PHA monomers have been identified with the type and distribution of these monomers dictating

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the final polymer properties, extending from rigid plastics to elastic rubbers. The two most

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investigated

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poly(3-hydroxybutyrate-co-3-hydroxyvalerate) (PHBV)3. PHB is hard to process into

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commodity goods because is stiff and brittle, has a high degree of crystallinity and the melting

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temperature is close to its decomposition temperature, which restricts its use. The introduction of

types

of

PHA

are

poly(3-hydroxybutyrate)

(PHB)

and

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3-hydroxyvalerate (3HV) units to form PHBV disrupts the highly crystalline PHB structure,

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resulting in a polymer with enhanced mechanical properties, quicker degradation rates, improved

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processing and greater potential for commodity applications4–6.

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Commercial PHA production is typically done with pure cultures of wild-type or genetically

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modified microorganisms7. The main factors restricting wider PHA utilization are

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inconsistencies in PHA structure and hence properties; high production costs associated with the

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use of refined carbon sources; the discontinuous production in batch or fed-batch; the prevention

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of contamination and the use of large volumes of solvent in downstream processing8–10.

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Halophiles, salt loving microorganisms, are promising candidates with increasing interest for the

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economical large scale production of PHA11 because they have simple growth requirements and

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can utilize a wide variety of carbon sources as substrates12. More importantly, the extremely high

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salinity of the media drastically reduces the risk of contamination and the requirement for media

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and equipment sterilisation13, which in turn opens the possibility for the development of longer

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and continuous production campaigns or production in open ponds14,15. Amongst the halophiles,

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the extreme archaea H. mediterranei is of interest for the production of PHBV since it naturally

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produces the copolymer without the addition of precursors or structurally related carbon sources3

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and the polymer accumulation is associated with cell growth, hence no specific nutrient

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limitation is required leading to straight-forward fermentations. Furthermore, recovery of the

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biopolymer is solvent-free because in a hypotonic environment the high intracellular salinity

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leads to cell lysis, thus reducing the use of toxic solvents and contributing towards the

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development of greener, cheaper and potentially more sustainable processes16,17.

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The number of publications in which H. mediterranei is used as PHA producer has increased

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in recent years with the main focus on the utilisation of different wastes as cheap substrates18–21,

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the development of new fermentation techniques22,23 and the study of H. mediterranei

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metabolism3,24–27, with only a few dedicated to the investigation of the PHA characteristics6,28,29.

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The thermal properties of PHA from H. mediterranei have been frequently reported6,19–21,28 but

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there is limited information regarding the biopolymer mechanical properties29. Koller30, Zhao5

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and co-workers found significant differences between the PHBV from haloarchaea and bacteria,

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so the biopolymer properties from these microorganisms might not be directly comparable. Thus,

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the characterisation of biopolymers from haloarchaea is required to identify potential

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applications based on the unique PHA properties. Additionally, the production of PHBV with

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high 3HV fraction is normally limited by the 3HV precursor toxicity. For example, Han and

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coworkers29 reported the production of PHBV with 60 mol% 3HV at expenses of biomass and

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PHA synthesis and when sufficient amount of cells were generated the final copolymer only had

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an 3HV content of 46.8 mol%. Similarly, McChalicher and coworkers31 wanted to study the

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properties of block copolymers with fractions containing 60 mol% 3HV but such composition

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was not attainable using fructose and valerate co-feeding. Thus, examples in literature of such

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copolymers are scarce and their potential is not fully explored.

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The genome of H. mediterranei32 encodes enzymes for the β-oxidation pathway and it has

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been suggested that the strain can utilise short-chain fatty acids as a carbon source29. Han and

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coworkers29 started to explore the possibility using short-chain fatty acids by co-feeding C5:0

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and glucose and synthesised PHBV with 3HV content ranging from 7 to 57 mol% that showed

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good haemostatic properties. However, there are no reports regarding the utilization of fatty

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acids as sole substrates for cell growth and PHA production. In this study VFA C2:0, C3:0, C4:0,

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C5:0 and C6:0 have been used as a sole carbon source for H. mediterranei growth and PHA

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production. PHBV with a wide range of composition was produced, from PHB rich copolymers,

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when feeding solely carbon-even VFA, to PHV rich copolymers, when only carbon-odd VFA

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were supplied. More importantly, it was found that when cells were grown with C4:0/C5:0

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mixtures, the 3HV fraction in the PHBV copolymer was directly proportional to percentage of

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C5:0 in the mixture. Co-feeding or sequential feeding led to the generation of random or block

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and blend copolymers respectively. Thus, the composition and microstructure of the copolymers

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can be controlled by regulating the C4:0:C5:0 ratios in the feed and the order of addition. The

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different PHBV produced had ultra-high molecular weight and showed excellent thermal and

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mechanical properties. This study demonstrates that it is possible to produce bespoke PHBV

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polymers with specific characteristics by controlling the feed composition order of addition to

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meet the criteria for commodity uses.

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EXPERIMENTAL

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Microorganism and culture conditions

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The microorganism used in all the experiments was H. mediterranei DSM 1411. A 20 mL seed

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culture was initiated from vials stored at −80°C33 and grown for 24 h at 37°C and 200 rpm in

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minimal synthetic medium (MSM) supplemented with 10 g/L of glucose. The culture was then

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transferred to a second 200 mL seed culture grown under the same conditions for 36 h in order to

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generate sufficient biomass to inoculate the production flask. Prior to the inoculation of the

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production flask, the second seed culture was concentrated by centrifugation at 7000 rpm for

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5 min (Sigma 6-16S, SciQuip) and re-suspended with MSM. The production flasks were

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inoculated to an initial OD600 of 1.4. The production flasks contained MSM supplemented with

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different fatty.

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For the screening experiment (exp. A-E 1-3), cells were grown in 100 mL of MSM with

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saturated fatty acids from C2:0 to C11:0, namely ethanoic acid (C2:0), propanoic acid (C3:0),

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butanoic acid (C4:0), pentanoic acid (C5:0), hexanoic acid (C6:0), heptanoic acid (C7:0),

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octanoic acid (C8:0), nonanoic acid (C9:0), decanoic acid (C10:0) and undecanoic acid (C11:0).

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The fatty acids were added at carbon concentrations of 0.10, 0.25 and 0.50 M, see Table 1

115

(supporting information). The cells were cultivated for 94 h to 335 h until no further growth was

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detected.

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The remaining experiments (A4-E4, F1-F3, G1, and G2) were carried out in 200 mL of MSM

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with different VFA added in a fed-batch feeding strategy, see Table 1 and Table 2 for details

119

(supporting information). For the fed-batch feeding strategy, the initial carbon concentration in

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the production flasks was 0.1 M, with two subsequent 10 mL additions of MSM containing 4 M

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carbon of the corresponding VFA to achieve a final carbon concentration of 0.50 M. For

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experiments A4-E4 ethanoic acid (C2:0), propanoic acid (C3:0), butanoic acid (C4:0), pentanoic

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acid (C5:0), hexanoic acid (C6:0) were used. The cells were cultivated for 144 h to 262 h until no

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further growth was detected. Experiments F1-F3 were carried out for 213 h by co-feeding a

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mixture of butanoic and pentanoic acid (C4:0:C5:0) at carbon ratios of 25:75, 50:50 and 75:25.

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For experiments G1 and G2, sequential feeding of butanoic acid (C4:0) and pentanoic acid

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(C5:0) was performed. Specifically, in experiment G1 cells were initially grown in C4:0 and

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sequentially fed first at 92 h with one addition of C4:0 followed by a second addition of C5:0 at

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160 h; and in experiment G2 cells initially grown in C5:0 and sequentially fed with first at 92 h

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one addition of C5:0 followed by a second addition of C4:0 at 160 h. The total length of the

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cultivation was 213 h.

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All the experiments were carried out at 37°C and 200 rpm and were performed in duplicate

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(experiments A-E 1-3, F1-F3, G1, G2) or quadruplicate (A4-E4). Sterilisation of the glassware

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and media was not done at any stage during the experiment and potential contamination was

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monitored via regular microscopic observations and streaking on agar plates.

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The minimal synthetic medium (MSM) contained (g/L): 156 NaCl, 13 MgCl2 • 6 H2O,

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20 MgSO4 • 7 H2O, 1 CaCl2 • 6 H2O, 4 KCl, 0.2 NaHCO3, 0.5 NaBr, 2 NH4Cl, 0.5 KH2PO4,

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0.005 FeCl3, 15 1,4-Piperazinediethanesulfonic acid (PIPES) and 10 mL/L21 trace element

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solution

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0.03 MnCl2 • 4 H2O, 0.3 H3BO3, 0.2 CoCl2 • 6 H2O, 0.01 CuCl2 • 2 H2O, 0.02 NiCl2 • 6 H2O,

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0.03 Na2MoO4 • 2 H2O. The medium and different substrate additions were adjusted to pH

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6.8±0.2 with NaOH prior to use.

SL6.

Trace

element

solution

SL6

contained

(g/L):

0.1 ZnSO4 • 7 H2O,

143 144

Determination of optical density and cell dry mass

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Samples for optical density (OD600) determination were centrifuged at 13000 rpm for 5 min

146

(MiniSpin, Eppendorf), the cells re-suspended in 10% (w/v) NaCl solution and optical density

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was measured at 600 nm in a UV-visible spectrophotometer (UVmini-1240, UV-VIS

148

spectrophotometer, Shimadzu). For the cell dry mass (CDM) measurement, 2 mL cell culture

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were transferred in ceramic crucibles, dried at 105°C to constant weight and subsequently heated

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in a P300 furnace (Nabertherm) at 400°C for 4h. CDM was calculated as the weight difference

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between the samples before and after the furnace heating step.

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Quantification of PHA and composition characterization with GC-FID

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For PHA quantification, 2 mL of cell culture was centrifuged at 13000 rpm for 5 min

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(MiniSpin, Eppendorf). The pellet was re-suspended with distilled water, transferred to pressure

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tubes and dried at 105°C to constant weight. The methanolysis sample preparation procedure and

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gas chromatography method was used as previously described

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(mPHA/CDM) was calculated by divining the PHA produced by the CDM obtained.

33

. The PHA accumulation

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PHA recovery, purification and film preparation

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To recover the PHA from the biomass, the samples were first centrifuged at 7000 rpm for

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10 min (Sigma 6-16S, SciQuip), the pellet re-suspended with the same volume of distilled water

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with 0.1% sodium dodecyl sulphate (SDS) and then continuously agitated for 30 min. This

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procedure was repeated 2 to 5 times until a white PHA pellet was obtained. The PHA was

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washed one final time with distilled water and the PHA pellet was dried.

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For PHA purification the PHA pellet was dissolved in CHCl3 to an approximate final

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concentration of 10 g/L, and the obtained solution was then precipitated using 10 volumes of

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cold methanol under continuous stirring and then agitated for 20 min. Finally, the PHA was

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recovered by decantation or centrifugation at 7000 rpm for 5 min and dried at 30°C.

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PHA films were prepared using the solvent casting technique. Approximately 0.1 g of purified

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PHA was dissolved in 10 mL CHCl3 and the solution poured into 60 cm PTFE dishes. The dishes

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were covered with a glass lid and the CHCl3 left to evaporate. The films obtained were semi-

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transparent with an average thickness of 32 ± 8 μm and were stored at room temperature for a

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minimum of 2 weeks before testing.

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Quantification of fatty acids with HPLC and yields calculation

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Fatty acids in the cell-free supernatant were quantified using high-performance liquid

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chromatography (UltiMate3000 Dionex HPLC system, Thermo Scientific) equipped with an

176

Aminex HPX-87H (Biorad) column coupled to a UV detector (HPLC-UV). The mobile phase

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was 5 mM H2SO4, the flowrate was set to 1.0 mL/min, the operating temperature was 50°C and

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the detecting wavelength was 210 nm.

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The biomass yield (YX/S) was calculated by dividing the C-biomass generated by the C-

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substrate consumed. The biomass value was obtained by subtracting the amount of PHA from

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the cell dry mass and taking the elemental composition of the cell biomass as

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CO0.63H1.57N0.13P0.02S0.01 with molar mass 26.4 g/mol34. The PHA yield (YPHA/S) was calculated

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by dividing the C-polymer synthesized by the C-substrate consumed.

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Determination of molecular weight with GPC

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The determination of PHA molecular weight was done as previously described 33.

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Determination of PHBV microstructure and composition with NMR

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Purified PHA was dissolved in CDCl3 to a concentration of approximately 20 mg/mL and a

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B500 MHz Avance II+ (Bruker) was used to record 1H NMR and

189

temperature. PHBV composition was calculated from the 1H NMR spectra using the relative

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intensities of the methyl peaks corresponding to 3HB and 3HV units. 13C NMR data was used to

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calculate nearest neighbour statistics D value35, see equation 1, and determine the PHBV

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microstructure. D value is indicative of the distribution of the 3HB and 3HV monomer units:

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statistically random distribution are characterised by D values close to 1, block polymers show D

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values greater than 1 and alternating copolymers have D values smaller than 135,36. D =

13

C NMR spectra at room

FHBHB × FHVHV FHBHV × FHVHB

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Equation 1. FHBHB is fraction of 3HB adjacent to 3HB monomers, FHVHV is fraction of 3HV

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adjacent to 3HV monomers, FHBHV is fraction of 3HB adjacent to 3HV monomers and FHVHB is

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fraction of 3HV adjacent to 3HB monomers.

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Determination of the thermal properties using DSC and TGA

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A differential scanning calorimeter DSC Q100 (TA Instruments) was used for the

200

determination of the thermal properties of the obtained PHA samples. Briefly, 2.5 ± 0.8 mg of

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polymer were initially heated to 200°C at 10°C/min and maintained at this temperature for

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5 min, the sample was then cooled to −20°C at 10°C/min, heated up to 200°C at 10°C/min and

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cooled to −20°C. The glass transition (Tg) and crystallization (Tc) temperature were determined

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from the onset point and the melting temperature (Tm) was determined at the minimum of the

205

peak.

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The thermal stability of the PHA was investigated by thermogravimetric analysis with

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TGA550 (TA instruments). The samples were heated at 5°C/min to 500°C and the gas flow rate

208

was set to 25 mL/min. The decomposition temperature (Td) was determined at the onset point.

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Tensile testing of PHA films

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Solvent cast film strips of 5 × 25 mm were tested with a 3344 Testing System (Instron)

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equipped with a 10 N load cell at a tensile rate of 5 mm/min at room temperature. The Young’s

212

modulus, tensile strength and elongation at break were calculated from the stress-strain curve.

213 214

RESULTS AND DISCUSSION

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PHA production using fatty acids from C2:0 to C11:0

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Fatty acids were used as the sole carbon source for H. mediterranei growth and PHBV

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production. Saturated fatty acids with chain lengths varying from C2:0 to C11:0, at three

218

different carbon concentrations of 0.10 M, 0.25 M and 0.50 M, were initially tested in a

219

screening experiment (exp. A-E 1-3). The results obtained show that high fatty acid

220

concentrations were toxic for the cells and inhibited cell growth, hence a new set of experiments

221

was performed following a fed-batch feeding strategy (exp. A-E 4): the initial fatty acid carbon

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concentration in the culture media was set to 0.1 M and two additions of 0.2 M were performed

223

to reach a final concentration of 0.5 M.

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The results for the screening and fed-batch experiments are summarised in Table 1 (supporting

225

information). Cell growth was compared by determining the maximum specific growth rate

226

(µmax) and cell dry mass (CDM). In the screening experiment, cell growth was only observed

227

with C2:0 to C5:0 at all carbon concentrations tested and C6:0 at 0.10 and 0.25 M. No biomass

228

was detected for cultures containing C6:0 at 0.50 M or C7:0 to C11:0 at any concentration tested.

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The variation in µmax for C2:0, C3:0 and C4:0 was relatively small for the concentrations tested

230

and the CDM obtained increased or remained constant with increasing amount of substrate, from

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an average of 2.4 g/L for 0.10 M to a maximum of 6.70 g/L for condition B3. There was a

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substantial decline in µmax as the carbon concentration of C5:0 or C6:0 increased: µmax decreased

233

from 0.017 h-1 to 0.006 h-1 for C5:0 and from 0.011 h-1 to no growth for C6:0. A similar trend

234

was observed in CDM with increasing C5:0 and C6:0 concentrations. The results clearly showed

235

that substrate toxicity increased with fatty acid length and carbon concentration. It is often

236

reported in literature that the PHV precursors propionate (C3:0) and valerate (C5:0) inhibit cell

237

growth. Han and coworkers29 observed a significant reduction in maximum CDM when

238

H mediterranei was grown on glucose and 17mM of valerate (equivalent to a carbon

239

concentration of 0.085 M). To overcome the toxicity problem, a fed-batch feeding strategy was

240

successfully employed (exp. A-E 4). The fed-batch feeding allowed the production of similar or

241

higher amounts of CDM compared to 0.5 M batch cultures (exp. A-E 3), thus allowing the

242

generation of sufficient biomass and PHA under otherwise toxic conditions. Interestingly, µmax

243

for fed-batch (exp. A-E 4) cultures and for the cultures fed with a carbon concentration of 0.1 M

244

(exp. A-E 1) are comparable, indicating that the subsequent addition of substrate in the fed-batch

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experiment did not have a negative effect on cell growth. Fed-batch cultivation was especially

246

beneficial when C5:0 and C6:0 were used as a carbon source as it permitted biomass growth and

247

polymer accumulation.

248

The intracellular PHA content ranged from 5% to 23% in batch cultures and was between 11%

249

and 27% for fed-batch cultures, see Table 1. The values are comparable to other flask

250

fermentations reported in literature26,37,38, although higher PHA accumulations can be achieved

251

in bioreactor fermentations or in complex media containing hydrolysates or wastes19,21,28,39,40.

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The polymer composition was determined by GC and 1H NMR and similar results were obtained

253

with each technique. PHBV copolymers with varied composition were obtained: carbon-even

254

VFA produced a PHBV polymer rich in 3HB fraction (3HB > 90 mol%) while carbon-odd VFA

255

generated a PHBV polymer rich in 3HV fraction (3HV > 87 mol%). When C2:0 was used as

256

carbon source a copolymer with an 8.2 mol% 3HV synthesised, a composition similar to the

257

10 mol% 3HV obtained from glucose33. Since glucose is metabolised to acetyl-CoA to produce

258

PHBV, a likely explanation is that C2:0 is converted to the same intermediate and follows the

259

same pathway to generate PHBV. In that case, the end polymer would have a similar

260

composition irrespective of the original substrate used. The PHBV polymer with 86.9 mol%

261

3HV obtained from C3:0 indicates that the substrate is used to generate both 3HB and 3HV

262

units, a phenomenon well documented in literature4,41–43. Bhubalan4, Doi42 and co-workers

263

reported that twice the amount of C3:0 was required to generate PHBV polymer with a certain

264

3HV content when compared to C5:0 since some of the C3:0 supplied was directed towards 3HB

265

synthesis. The loss of the 3HV precursor could be due to oxidative decarboxylation, which

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converts propionyl-CoA to acetyl-CoA, hence a 3HV precursors is converted to a

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3HB precursor44. High purity homopolymer PHB was generated from C4:0 and C6:0 and PHV

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from C5:0. This indicates that C4:0 and C5:0 are directly incorporated into the polymer chain

269

without breaking the carbon skeleton41,42. However, C6:0 is first converted into a PHB precursor

270

and then incorporated into the polymer chain as 3HB.

271

The results presented show that VFA are promising substrates for the production of PHBV by

272

H. mediterranei. VFA can be economically obtained by anaerobic fermentation of different

273

organic wastes45, which could contribute towards a reduction of the production cost.

274

Additionally, scaling up the process into multistage batch46 or continuous reactors23 could

275

enhance polymer yields, thus making the biopolymer production more economically viable.

276

Production of PHBV with controlled composition and microstructure

277

The experiments described in the previous section revealed that when C4:0 and C5:0 were

278

used as the sole carbon source in H. mediterranei cultures, high purity PHB and PHV were

279

obtained. In light of these results, a new set of experiments was designed to control the PHBV

280

composition and microstructure by regulating the C4:0/C5:0 proportions in the substrate mixture

281

and the time-sequence of addition. For the generation of random PHBV polymers, C4:0/C5:0

282

mixtures were co-fed to cell cultures; the mixtures contained 25%, 50% or 75% carbon coming

283

from C4:0, resulting in C4:0:C5:0 molar ratios of 29:71, 56:44 and 79:21 (exp. F1-F3). For the

284

generation of block and blend polymers, sequential feeding of C4:0 followed by C5:0 and

285

vice versa was performed; the C4:0:C5:0 molar ratios tested were of 65:35 and 45:54 (exp. G1,

286

G2). The total carbon fed in all cases was 0.50 M, the initial carbon concentration was set to

287

0.1 M and two additions of 0.2 M were performed.

288

The results for experiments F1-F3, G1, G2 are summarised in Table 2 (supporting

289

information). Similar cell growth, PHBV production and accumulation were obtained with the

290

co-feeding or sequential feeding of C4:0/C5:0 mixtures and also with the cultures grown with

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pure C4:0 and C5:0 (see Table 1, exp. C4 and D4). The biomass yield (YX/S) and PHA yield

292

(YPHA/S) reported in Table 2 are comparable to the 0.30 and 0.31 Cmol/Cmol biomass yield and

293

the 0.12 and 0.15 Cmol/Cmol PHA yield obtained in experiments C4 and D4 respectively. Thus,

294

the cell cultures have similar performances in terms of cell growth and PHBV synthesis

295

regardless of the substrate used and the feeding sequence, indicating that the composition of the

296

feed only influences the proportion of 3HB and 3HV in the final copolymer, rather than the

297

efficiency of PHBV production.

298

Polymer composition was determined by GC and 1H NMR and comparable results were

299

obtained using both techniques. In all cases, the polymer obtained was a PHBV copolymer with

300

increasing 3HV fraction as the C5:0 percentage in the mixture increased, see Table 2. Strikingly

301

there is a strong linear correlation between the percentage of C5:0 in the feed and the 3HV

302

fraction in PHA polymer, with a correlation coefficient (R2) greater than 0.98, see Figure 1. This

303

correlation exists regardless of the feeding strategy used, co-feeding or sequential feeding, and

304

covers the complete spectrum of PHBV compositions, from pure PHB to pure PHV. Therefore, it

305

is possible to produce PHBV polymers with a pre-defined composition by simply feeding the cell

306

culture with a C4:0/C5:0 mixture with the same C5:0 molar ratio as the desired 3HV fraction.

307

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Figure 1. Relationship between percentage of C5:0 in the feed and 3HV fraction in PHBV

310

polymers obtained with co-feeding or sequential feeding of C4:0/C5:0 mixtures (random PHBV

311

square solid symbols, F1-F3; block PHBV circle, G1; blend PHBV triangle, G2). Error bars

312

show the standard deviation from the mean.

313

PHBV copolymers are desired because of their improved thermal and mechanical properties.

314

However, PHBV copolymers with more than 50 mol% 3HV cannot be easily produced because

315

3HV precursors are normally toxic for the cells

316

of 3HV rich PHBV copolymers with a pre-defined composition can be easily accomplished

317

when C4:0 and C5:0 mixtures are used as sole carbon source in H. mediterranei cultures. The

29,31

. This study demonstrates that the synthesis

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318

simple and direct control over the complete range of PHBV composition demonstrated in this

319

study is a significant step forward towards the study of such polymers and towards the

320

production of bespoke polymers for specific applications such as biomedical implants or food

321

packaging.

322

For experiments F1-F3 and G1-G2, PHBV content and composition was analysed at the start,

323

before each subsequent addition of fatty acid (addition 1 at 92 h and addition 2 at 160 h) and at

324

the end of the experiment at 213 h. Figure 2 shows the change in polymer composition over time.

325

The 3HV content of the PHA samples obtained from co-feeding of C4:0/C5:0 mixtures (exp. F1-

326

F3) showed minor variations throughout the cultivation period, indicating that both substrates are

327

metabolised simultaneously and thus it can be concluded that H. mediterranei does not have a

328

preference between C4:0 and C5:0. In the sequential feeding experiment G1, when C4:0 was

329

present in the initial medium as well as in addition 1 only PHB was synthesised (in Figure 2,

330

displayed as 0 3HV mol%) and after addition 2, when C5:0 was added, a 3HV fraction was

331

detected. Similarly, culture G2 grew with C5:0 until addition 2, thus 3HV fraction in the polymer

332

remained above 90% until addition 2, after which the 3HV fraction decreased to 60.5 mol% due

333

to the addition of C4:0 and production of 3HB.

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Figure 2. Variation of the 3HV fraction of the PHBV over time from the copolymers obtained

336

with co-feeding and sequential feeding of C4:0/C5:0 (random PHBV square solid symbols,

337

F1 dash-dot, F2 dash, F3 dot; block PHBV open circle, G1; and blend PHBV open triangle, G2.

338

For G1 and G2, the substrate added at each stage is denoted in bold and the substrate from

339

previous additions is denoted in grey). Error bars show the standard deviation from the mean.

340

To discern the PHBV microstructure of the polymers obtained with co-feeding and sequential 13

C NMR data was used to determine the nearest neighbour statistics D value35. The D

341

feeding,

342

value is the ratio between the fraction of the same type of adjacent units (3HV*3HV and

343

3HB*3HB) over fraction of different type adjacent units (3HV*3HB and 3HB*3HV). Table 3

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344

(supporting information) shows that co-feeding of C4:0 and C5:0 mixtures (exp. F1-F3)

345

produced random copolymers with D values around 1 and that sequential feeding (G1, G2)

346

generated PHBV with D values much greater than 1, suggesting the formation of block

347

copolymers. Specifically, a PHBV characterised with a D value of 21 was obtained in the

348

sequential feeding experiment G1, showing that 3HV and 3HB units are found next to each other

349

in the polymer chain thus forming a block polymer, see Figure 3. However, the PHBV from

350

experiment G2 had a D value greater than 5000, an indication that the incidence of 3HV units

351

next to 3HB units is nearly non-existent as shown in figure 3, i.e. there is an absence of polymer

352

changing points between 3HB and 3HV regions. Thus, the PHBV from G2 is in fact a blend of

353

PHB and PHV polymer chains. The thermal analysis confirmed the block and blend nature of

354

such polymers. In experiment G2, cell growth decelerated just before addition 2 likely due to

355

substrate depletion (data not shown). When addition 2 was performed, cell growth and polymer

356

synthesis continued but the temporary substrate depletion might have influenced PHA formation.

357

GC results show that the amount of 3HV remained constant between addition 2 until the end of

358

the cultivation and during that period only PHB was produced. A possible explanation for the

359

synthesis of a blend polymer is that after addition 2, the new substrate fed was used to synthesise

360

new polymer chains rather than to elongate existing ones. The coexistence of the two types of

361

polymer chain could explain the high polydispersity index of 2.8 obtained for experiment G2.

362

The results highlight the importance of addition time when performing sequential feeding. The

363

control over the microstructure of the polymer allows for the design of materials with unique

364

properties. Block polymers can display the characteristics of each constituent unit and potentially

365

show new properties that couldn’t be achieved otherwise47, such as improved mechanical and

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Biomacromolecules

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thermal properties48,49. Block polymers can also have improved cell adhesion, a desired

367

characteristic for scaffolding, wound healing and biomedical applications.

1 6 9 .7 1 6 9 .6 1 6 9 .5 1 6 9 .4 1 6 9 .3 1 6 9 .2

7 2 .2 7 2 .1

7 2 .0 7 1 .9 3 9 .0 3 8 .9

3 8 .8

3 8 .7

2 7 .0

2 6 .9 2 6 .8

9 .5

9 .4

368 369

Figure 3. a) PHBV chemical structure and

370

molecule. b) 13C-NMR resonance splittings for 3HV units from random, block and blend PHBV.

371

Asterisk (*) designates interaction between units; interaction between different units (3HB*3HV

372

or 3HV*3HB) is shown in italics.

13

C-NMR chemical shifts of carbons from PHBV

373

PHBV characterisation

374

PHBV with 3HV fractions above 50 mol% are rarely reported and with no characterisation of

375

their mechanical or thermal properties. Furthermore, there is limited information about the

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376

mechanical properties of PHA from halophiles. This section contributes to an expansion of

377

knowledge in the aforementioned areas. The molecular weight and thermal properties of random,

378

block and blend HBV copolymers obtained from cultures grown in C2:0 to C6:0 (exp. A-E 4)

379

and C4:0/C5:0 mixtures (F1-F3, G1-G2) were investigated. In addition, the mechanical

380

properties of cast films were also measured. The results obtained are summarised in Table 3.

381

Molecular weight

382

PHBV from C2:0 (exp. A4) had the lowest average molecular weight (Mw) of 0.46 × 106 g/mol

383

and a remarkably low polydispersity index (PDI) of 1.3. The rest of the PHBV copolymers

384

obtained showed Mw in the range of 1.7 to 3.4 × 106 g/mol with typical values for PDI between

385

1.8 and 2.8, see Table 3. PHBV obtained from C4:0 and C5:0 mixtures (F1-F3, G1-G2) exhibited

386

a Mw around 3 × 106 g/mol and could be considered ultra-high Mw PHA (Mw > 3 × 106 g/mol), a

387

preferable type of PHA because of its enhanced mechanical strength50,51. PHA from halophiles

388

often shows relatively low Mw of 0.1 to 0.6× 106 g/mol20,21,28,52,53 although PHA with relatively

389

high degree of polymerisation of 1 to 2 × 106 g/mol has been previously synthesised5,6,29,54–56.

390

However, this is the first time ultra-high Mw PHA has been reported. Han and coworkers29

391

obtained PHA with 1 to 2 × 106 g/mol when glucose and fatty acids were used in H. mediterranei

392

cultures. Results from this study and from Han and coworkers suggest that fatty acids are

393

promising substrates for the generation of ultra-high Mw biopolymer with H. mediterranei,

394

without the need for genetic manipulation.

395

Results from Table 3 show that the 3HV content in the polymer did not influence the Mw of the

396

molecule, thus the incorporation of 3HV units did not disrupt the polymer chain growth.

397

However, cells which grow slower synthesised PHBV with higher Mw (except for sample F2).

398

This result might reflect that a slower metabolism is beneficial to produce polymers with high

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399

degree of polymerisation. As expected PDI values increased with Mw, demonstrating a more

400

diverse polymer chain population with longer chain length polymers.

401

Mechanical properties

402

In order for a material to be appropriate within a given application, it is important to

403

understand its mechanical properties. In this regard, PHBV films were prepared using the

404

cast-solvent method with chloroform and the obtained films were subjected to an uniaxial

405

extension test to determine the following mechanical properties: Young’s modulus, a measure of

406

polymer stiffness; ultimate tensile strength, a measure of polymer toughness used to determine

407

the brittleness or ductility of a material; and elongation at break, a measure of polymer strength

408

prior to permanent plastic deformation31,57.

409

PHB obtained from C4:0 and C6:0 (experiments C4 and E4) had the highest Young’s modulus

410

above 1000 MPa, see Table 3, which is in agreement with 1500 MPa for pure PHB58 and similar

411

to 1700 MPa for polypropylene (PP)59. For random polymers the introduction of 3HV units into

412

the polymer chain interrupted the highly crystalline PHB structure, which reduced the Young’s

413

modulus and thereby improved the polymer elasticity, see Figure 4. However, the decrease in

414

stiffness was only observed for PHBV with 0-44 mol% 3HV fractions and above this percentage

415

the biopolymers had similar elasticity, with Young’s modulus values close to 390 MPa58 for

416

PHV and comparable to 200 MPa from low-density polyethylene (LDPE)59. Block copolymer

417

G1 showed a comparable degree of elasticity to random PHBV with >40 mol% 3HV despite

418

having an 3HV content of 26 mol%. On the other hand, the 60 mol% 3HV copolymer blend G2

419

had a Young’s modulus of 782.3 MPa, showing an elastic behaviour more similar to PHB rich

420

polymers due to the nature of its microstructure. These results highlight the importance of 3HV

421

being incorporated together with 3HB into the chain to increase elasticity.

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422 423

Figure 4. Young’s modulus (solid symbols) and tensile strength (open symbols) in relation to the

424

3HV fraction found in PHBV random copolymers (squares), block copolymer (circle) and blend

425

(triangle) polymer. Error bars show the standard deviation from the mean.

426

PHB rich polymers were the strongest with tensile strength of approximately 20 MPa and

427

comparable to 18 MPa for PHB57. The introduction of 3HV units into the polymer chain

428

decreased the tensile strength, see Figure 4, thus making the copolymers easier to process in

429

comparison to PHB. Again, the copolymer blend from exp. G2 was the exception and despite

430

having 60.5 mol% 3HV showed a relatively high strength value of 14.5 MPa due to its

431

microstructure. The films from experiments C4, E4, F3 and G2 had similar strength to the

432

10 MPa from LDPE59 or to the 16 MPa from polycaprolactone (PLC)60.

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Biomacromolecules

433

PHB and PHBV copolymers are known for their brittleness31,57. Elongation at break between

434

6.1 and 13.2% were observed and ductility increased at higher 3HV fractions regardless of the

435

microstructure. PHB rich polymers showed the smallest elongation at break of approximately

436

2.5%, in agreement to 3-5% of PHB58,61. Although PHBV copolymers were less brittle than pure

437

PHB, the copolymers broke at low elongations compared to some reports in literature. On the

438

other hand, the films were tested two weeks after preparation and PHBV quickly ages and

439

becomes brittle in less than 3 days31; therefore even if the films from random PHBV might have

440

been more ductile initially, by the time the test was performed they would had lost their ductility

441

and therefore break at low elongations.

442

Similar values for Young’s modulus and tensile strength of random and block copolymers

443

were obtained, suggesting that the composition, rather than the microstructure, had a greater

444

influence on the elasticity and strength of the polymers. The previous observation agrees with the

445

investigations of structure-property relationship of PHBV copolymers performed by

446

McChalicher and coworkers31. However, blend copolymer from G2 was stiffer and stronger than

447

expected for its composition, indicating than in this case the microstructure is the main driving

448

force determining the polymer properties. PHBV copolymers show good strength and elasticity,

449

comparable with oil-derived plastics such as PP, LDPE or PLC, but the extreme brittleness still

450

hinders its wider use in commodity applications. Polymer toughness could be improved by the

451

synthesis of block polymers, which can be easily performed in H. mediterranei cultures with the

452

controlled sequential feeding of C4:0 and C5:0.

453

Thermal properties

454

The thermal characterisation of PHBV samples was performed with DSC and results are

455

summarised in Table 3. The glass transition temperature (Tg) was only detected for random

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456

polymers with 3HV fractions greater than 20 mol%. The Tg for PHV is between −11°C and

457

−16°C62, in agreement with −17.8°C recorded for PHV sample D4. A linear decrease in Tg from

458

−0.5°C to −17.8°C was observed with increasing 3HV fractions, indicating an increase in

459

polymer chain molecular mobility in the amorphous phase36,63. Crystallisation temperature (Tc)

460

varied between 34.7°C and 117.2°C. The absence of Tc peaks could be an indication of the

461

amorphous nature of random polymers48.

462

The melting temperature (Tm) of PHB polymer from samples C4 and E4 was around 165°C,

463

which is similar to 160-177°C for pure PHB64. PHV from sample D4 showed a melting peak at

464

108.0°C, also in agreement with 107-112°C reported for pure PHV62,65. Polymers with

465

8 - 72 mol% 3HV showed two melting peaks in the DSC curve, while 3HB or 3HV rich

466

copolymers only had one Tm similar to the pure polymer, see Figure 5. The block and blend

467

copolymer G1 and G2 showed a Tm around 110°C, corresponding to the 3HV fraction of the

468

polymer; and a Tm around 165°C, for the 3HB fraction of the polymer. Specifically, sample G2

469

showed two Tm at 167.8°C and 175.5°C probably due to a melt-recrystallisation process63. The

470

presence of two well separated melting peaks in the samples G1 and G2 with a similar Tm to pure

471

PHB and PHV indicate the coexistence of two main fractions immiscible in the melt, being a

472

clear indication of the block and blend nature of the samples, providing further confirmation of

473

the microstructure results obtained with

474

due to the interaction between 3HB and 3HV units. In random copolymers, Tm decreased with

475

3HV fraction and PHBV polymers with >70 mol% 3HV have Tm equal or below 110°C, see

476

Figure 5. A minimum of the melting point versus composition has been previously observed at

477

around 40-50 mol% 3HV; the change has been attributed to the changeover from PHB crystalline

478

lattice to PHV crystalline lattice observed between 47 and 52 mol% 3HV36,62.

13

C-NMR. Random copolymers have shifted Tm peaks

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479 480

Figure 5. Melting temperatures (Tm) in relation to the 3HV fraction for PHBV random

481

copolymers. Error bars show the standard deviation from the mean.

482

Polymer decomposition temperatures (Td) were analysed by TGA and the results are

483

summarised in Table 3. Td obtained for all samples was between 220.8 to 267.4°C. Random

484

PHBV copolymers A4, B4 and F1 showed two Td, the first one around 225°C and the second one

485

at 360°C approximately. The weight loss after the first Td was 85%, 96% and 98% respectively.

486

For the remaining samples, the weight loss after Td was greater than 99%. One of the

487

disadvantages of PHB is its thermal instability since the temperature processing window, the

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Page 26 of 39

488

difference between melting and decomposition temperature, is small (35°C28), thus it is hard to

489

mould into commercial items. Figure 6 shows that the incorporation of 3HV units in the polymer

490

chain significantly increases the temperature processing window from 50-60°C for pure PHB to

491

above 120°C for polymers with 3HV content above 40 mol%. The blend copolymer G2 had a

492

similar Tm value to pure PHB despite having 60 mol% 3HV, which explains the similarity

493

between the temperature processing window of this copolymer and for rich PHB polymers.

494 495

Figure 6. Variation of temperature processing window with 3HV fraction for random PHBV

496

polymers. For samples with more than one Tm or Td, the highest Tm and lowest Td was used to

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497

calculate the temperature processing window. Error bars show the standard deviation from the

498

mean.

499

The results for the thermal analysis confirmed the synthesis of PHBV block and blend

500

polymers. The incorporation of 3HV units into PHB chain significantly decreased the melting

501

temperature and increased the temperature processing window. The blend PHB and PHV

502

copolymer showed similar characteristics to pure PHB, making random or block copolymers

503

more desirable in terms of thermal stability and ease of processing to finished goods.

504

CONCLUSIONS

505

Cell growth and PHBV production in H. mediterranei from fatty acids C2:0, C3:0, C4:0, C5:0

506

and C6:0 was demonstrated. Feeding solely C4:0 or C5:0 generated 3HB and 3HV rich polymers

507

respectively but more importantly copolymer composition and microstructure can be

508

manipulated by regulating the C4:0:C5:0 ratio in the feed and the order of addition. The

509

polymers obtained had an ultra-high Mw around 3 × 106 g/mol and showed similar elasticity and

510

strength as oil-derived plastics such as PP, LDPE or PLC. Copolymers with a 3HV fraction

511

greater than 50 mol% had lower melting temperatures in comparison to 3HB rich copolymers

512

and exhibited a wider range of temperature in which the copolymers can be processed. The PHB

513

and PHV blend had similar thermal and tensile characteristics to PHB, making the random and

514

block copolymers more desirable. Thermal and mechanical properties are key characteristics

515

when selecting materials for specific applications. Such properties can be enhanced by

516

manipulating copolymer composition as well as chemical microstructure. A suitable strategy to

517

control 3HV fraction in PHBV copolymers as well as its microstructure has been demonstrated,

518

with the ultimate goal to create a polymer with bespoke properties and greater industrial

519

potential.

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520

ASSOCIATED CONTENT

521

Supporting information

522 523 524 525

Page 28 of 39

Table 1 Cell growth, PHBV production and composition for cultures grown in C2:0 to C6:0 at different carbon concentrations and feeding strategy. Table 2 Cell growth, PHBV production and composition for cultures co-fed or sequentially fed with C4:0/C5:0 mixtures.

526

Table 3 Molecular weight, mechanical and thermal properties of PHBV copolymers obtained

527

from pure fatty acids (A4-E4), co-feeding or sequentially feeding C4:0/C5:0 mixtures (F1-F3 or

528

G1, G2 respectively).

529

AUTHOR INFORMATION

530

Corresponding Author

531

E-mail: *[email protected]

532

ACKNOWLEDGMENTS

533

The authors thank Dr. Matthew Cliff for carrying out the NMR analysis and Kamil Oster for

534

performing the DSC measurements. This research was funded by the Biotechnology and

535

Biological Research Council (BBSRC) grant BB/J014478/1.

536 537

REFERENCES (1)

538 539

Singh, M.; Kumar, P.; Ray, S.; Kalia, V. C. Challenges and Opportunities for Customizing Polyhydroxyalkanoates. Indian J. Microbiol. 2015, 55 (3), 235–249.

(2)

Keshavarz, T.; Roy, I. Polyhydroxyalkanoates: bioplastics with a green agenda. Curr.

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Biomacromolecules

540 541

Opin. Microbiol. 2010, 13 (3), 321–326. (3)

Han, J.; Hou, J.; Zhang, F.; Ai, G.; Li, M.; Cai, S.; Liu, H.; Wang, L.; Wang, Z.; Zhang,

542

S.; et al. Multiple propionyl coenzyme a-supplying pathways for production of the

543

bioplastic poly(3-Hydroxybutyrate-co-3-Hydroxyvalerate) in Haloferax mediterranei.

544

Appl. Environ. Microbiol. 2013, 79 (9), 2922–2931.

545

(4)

Bhubalan, K.; Lee, W.-H.; Loo, C.-Y.; Yamamoto, T.; Tsuge, T.; Doi, Y.; Sudesh, K.

546

Controlled

547

hydroxyvalerate-co-3-hydroxyhexanoate) from mixtures of palm kernel oil and 3HV-

548

precursors. Polym. Degrad. Stab. 2008, 93 (1), 17–23.

549

(5)

biosynthesis

and

characterization

of

poly(3-hydroxybutyrate-co-3-

Zhao, Y.; Rao, Z.; Xue, Y.; Gong, P.; Ji, Y.; Ma, Y. Biosynthesis, property comparison,

550

and hemocompatibility of bacterial and haloarchaeal poly(3-hydroxybutyrate-co-3-

551

hydroxyvalerate). Sci. Bull. 2015, 60 (22), 1901–1910.

552

(6)

Koller, M.; Hesse, P.; Bona, R.; Kutschera, C.; Atlić, A.; Braunegg, G. Biosynthesis of

553

high quality polyhydroxyalkanoate Co- And terpolyesters for potential medical

554

application by the archaeon Haloferax mediterranei. Macromol. Symp. 2007, 253, 33–39.

555

(7)

Jiang, Y.; Hebly, M.; Kleerebezem, R.; Muyzer, G.; van Loosdrecht, M. C. M. Metabolic

556

modeling of mixed substrate uptake for polyhydroxyalkanoate (PHA) production. Water

557

Res. 2011, 45 (3), 1309–1321.

558

(8)

Kourmentza, C.; Plácido, J.; Venetsaneas, N.; Burniol-Figols, A.; Varrone, C.; Gavala, H.

559

N.; Reis, M. A. M. Recent Advances and Challenges towards Sustainable

560

Polyhydroxyalkanoate (PHA) Production. Bioengineering 2017, 4 (2), 55.

ACS Paragon Plus Environment

29

Biomacromolecules 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

561

(9)

Page 30 of 39

Arcos-Hernández, M. V.; Laycock, B.; Donose, B. C.; Pratt, S.; Halley, P.; Al-Luaibi, S.;

562

Werker, A.; Lant, P. A. Physicochemical and mechanical properties of mixed culture

563

polyhydroxyalkanoate (PHBV). Eur. Polym. J. 2013, 49 (4), 904–913.

564

(10)

Kumar, P.; Mehariya, S.; Ray, S.; Mishra, A.; Kalia, V. C. Biotechnology in Aid of

565

Biodiesel Industry Effluent (Glycerol): Biofuels and Bioplastics. In Microbial Factories;

566

Kalia, V. C., Ed.; Springer, 2015; Vol. 1, pp 105–120.

567

(11)

Bhattacharyya, A.; Jana, K.; Haldar, S.; Bhowmic, A.; Mukhopadhyay, U. K.; De, S.;

568

Mukherjee, J. Integration of poly-3-(hydroxybutyrate-co-hydroxyvalerate) production by

569

Haloferax mediterranei through utilization of stillage from rice-based ethanol

570

manufacture in India and its techno-economic analysis. World J. Microbiol. Biotechnol.

571

2015.

572

(12)

573 574

Yin, J.; Chen, J.-C.; Wu, Q.; Chen, G.-Q. Halophiles, coming stars for industrial biotechnology. Biotechnol. Adv. 2014.

(13)

Quillaguamán, J.; Guzmán, H.; Van-Thuoc, D.; Hatti-Kaul, R. Synthesis and production

575

of polyhydroxyalkanoates by halophiles: Current potential and future prospects. Appl.

576

Microbiol. Biotechnol. 2010, 85, 1687–1696.

577

(14)

Garcia Lillo, J.; Rodriguez-Valera, F. Effects of Culture Conditions on Poly(beta-

578

Hydroxybutyric Acid) Production by Haloferax mediterranei. Appl. Environ. Microbiol.

579

1990, 56 (8), 2517–2521.

580 581

(15)

Tan, D.; Xue, Y. S.; Aibaidula, G.; Chen, G. Q. Unsterile and continuous production of polyhydroxybutyrate by Halomonas TD01. Bioresour. Technol. 2011, 102 (17), 8130–

ACS Paragon Plus Environment

30

Page 31 of 39 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

Biomacromolecules

582 583

8136. (16)

584 585

Oren, A. Industrial and environmental applications of halophilic microorganisms. Environ. Technol. 2010, 31 (8–9), 825–834.

(17)

Koller, M.; Maršálek, L.; de Sousa Dias, M. M.; Braunegg, G. Producing microbial

586

polyhydroxyalkanoate (PHA) biopolyesters in a sustainable manner. N. Biotechnol. 2017,

587

37, 24–38.

588

(18)

Bhattacharyya, A.; Saha, J.; Haldar, S.; Bhowmic, A.; Mukhopadhyay, U. K.; Mukherjee,

589

J. Production of poly-3-(hydroxybutyrate-co-hydroxyvalerate) by Haloferax mediterranei

590

using rice-based ethanol stillage with simultaneous recovery and re-use of medium salts.

591

Extremophiles 2014, 18, 463–470.

592

(19)

Chen, C. W.; Don, T. M.; Yen, H. F. Enzymatic extruded starch as a carbon source for the

593

production of poly(3-hydroxybutyrate-co-3-hydroxyvalerate) by Haloferax mediterranei.

594

Process Biochem. 2006, 41, 2289–2296.

595

(20)

Hermann-Krauss, C.; Koller, M.; Muhr, A.; Fasl, H.; Stelzer, F.; Braunegg, G. Archaeal

596

production of polyhydroxyalkanoate (PHA) Co- and terpolyesters from biodiesel industry-

597

derived by-products. Archaea 2013, 2013.

598

(21)

Pais, J.; Serafim, L. S. L. S.; Freitas, F.; Reis, M. a. M. M. Conversion of cheese whey

599

into poly(3-hydroxybutyrate-co-3-hydroxyvalerate) by Haloferax mediterranei. N.

600

Biotechnol. 2016, 33 (1), 224–230.

601 602

(22)

Lorantfy, B.; Ruschitzka, P.; Herwig, C. Investigation of physiological limits and conditions for robust bioprocessing of an extreme halophilic archaeon using external cell

ACS Paragon Plus Environment

31

Biomacromolecules 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

603 604

retention system. Biochem. Eng. J. 2014, 90, 140–148. (23)

605 606

Page 32 of 39

Mahler, N.; Tschirren, S.; Pflügl, S.; Herwig, C. Optimized bioreactor setup for scale-up studies of extreme halophilic cultures. Biochem. Eng. J. 2018, 130, 39–46.

(24)

Liu, G.; Cai, S.; Hou, J.; Zhao, D.; Han, J.; Zhou, J.; Xiang, H. Enoyl-CoA hydratase

607

mediates polyhydroxyalkanoate mobilization in Haloferax mediterranei. Sci. Rep. 2016, 6

608

(April), 1–11.

609

(25)

Martínez-Espinosa, R. M.; Richardson, D. J.; Butt, J. N.; Bonete, M. J. Respiratory nitrate

610

and nitrite pathway in the denitrifier haloarchaeon Haloferax mediterranei. Biochem. Soc.

611

Trans. 2006, 34 (Pt 1), 115–117.

612

(26)

Han, J.; Li, M.; Hou, J.; Wu, L.; Zhou, J.; Xiang, H. Comparison of four phaC genes from

613

Haloferax mediterranei and their function in different PHBV copolymer biosyntheses in

614

Haloarcula hispanica. Saline Systems 2010, 6, 9.

615

(27)

Liu, G.; Hou, J.; Cai, S.; Zhao, D.; Cai, L.; Han, J.; Zhou, J.; Xiang, H. A Patatin-Like

616

Protein Associated with the Polyhydroxyalkanoate (PHA) Granules of Haloferax

617

mediterranei Acts as an Efficient Depolymerase in the Degradation of Native PHA. Appl.

618

Environ. Microbiol. 2015, 81 (9), 3029–3038.

619

(28)

Don, T.-M.; Chen, C. W.; Chan, T.-H. Preparation and characterization of

620

poly(hydroxyalkanoate) from the fermentation of Haloferax mediterranei. J. Biomater.

621

Sci. Polym. Ed. 2006, 17 (12), 1425–1438.

622 623

(29)

Han, J.; Wu, L.-P.; Hou, J.; Zhao, D.; Xiang, H. Biosynthesis, Characterization, and Hemostasis Potential of Tailor-Made Poly(3-hydroxybutyrate-co-3-hydroxyvalerate)

ACS Paragon Plus Environment

32

Page 33 of 39 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

Biomacromolecules

624 625

Produced by Haloferax mediterranei. Biomacromolecules 2015, 16, 578–588. (30)

Koller, M.; Hesse, P.; Bona, R.; Kutschera, C.; Atlić, A.; Braunegg, G. Potential of

626

various archae and eubacterial strains as industrial polyhydroxyalkanoate producers from

627

whey. Macromol. Biosci. 2007, 7, 218–226.

628

(31)

629 630

McChalicher, C. W. J.; Srienc, F. Investigating the structure-property relationship of bacterial PHA block copolymers. J. Biotechnol. 2007, 132 (3), 296–302.

(32)

Han, J.; Zhang, F.; Hou, J.; Liu, X.; Li, M.; Liu, H.; Cai, L.; Zhang, B.; Chen, Y.; Zhou,

631

J.; et al. Complete genome sequence of the metabolically versatile halophilic archaeon

632

Haloferax mediterranei, a poly(3-hydroxybutyrate-co-3-hydroxyvalerate) producer. J.

633

Bacteriol. 2012, 194 (16), 4463–4464.

634

(33)

Ferre-Guell, A.; Winterburn, J. Production of the copolymer poly(3-hydroxybutyrate-co-

635

3-hydroxyvalerate) with varied composition using different nitrogen sources with

636

Haloferax mediterranei. Extremophiles 2017.

637

(34)

Lorantfy, B.; Seyer, B.; Herwig, C. Stoichiometric and kinetic analysis of extreme

638

halophilic Archaea on various substrates in a corrosion resistant bioreactor. N. Biotechnol.

639

2014, 31 (1), 80–89.

640

(35)

Kamiya, N.; Yamamoto, Y.; Inoue, Y.; Chiijb, R.; Doi, Y. Microestructure of bacterially

641

synthesized Poly(3-hydroxybutyrate-co-3-hydroxyvalerate). Macromolecules 1989, 22

642

(4), 1676–1682.

643 644

(36)

Laycock, B.; Arcos-Hernandez, M. V.; Langford, A.; Pratt, S.; Werker, A.; Halley, P. J.; Lant, P. A. Crystallisation and fractionation of selected polyhydroxyalkanoates produced

ACS Paragon Plus Environment

33

Biomacromolecules 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

645 646

Page 34 of 39

from mixed cultures. N. Biotechnol. 2014, 31 (4), 345–356. (37)

Lu, Q.; Han, J.; Zhou, L.; Zhou, J.; Xiang, H. Genetic and biochemical characterization of

647

the poly(3-hydroxybutyrate-co-3-hydroxyvalerate) synthase in Haloferax mediterranei. J.

648

Bacteriol. 2008, 190 (12), 4173–4180.

649

(38)

Hou, J.; Xiang, H.; Han, J. Propionyl Coenzyme A (Propionyl-CoA) Carboxylase in

650

Haloferax mediterranei: Indispensability for Propionyl-CoA Assimilation and Impacts on

651

Global Metabolism. Appl. Environ. Microbiol. 2015, 81 (2), 794–804.

652

(39)

Bhattacharyya, A.; Pramanik, A.; Maji, S. K.; Haldar, S.; Mukhopadhyay, U. K.;

653

Mukherjee, J. Utilization of vinasse for production of poly-3-(hydroxybutyrate-co-

654

hydroxyvalerate) by Haloferax mediterranei. AMB Express 2012, 2 (1), 34.

655

(40)

Koller, M.; Bona, R.; Braunegg, G.; Hermann, C.; Horvat, P.; Kroutil, M.; Martinz, J.;

656

Neto, J.; Pereira, L.; Varila, P. Production of polyhydroxyalkanoates from agricultural

657

waste and surplus materials. Biomacromolecules 2005, 6 (2), 561–565.

658

(41)

Lee, W. H.; Loo, C. Y.; Nomura, C. T.; Sudesh, K. Biosynthesis of polyhydroxyalkanoate

659

copolymers from mixtures of plant oils and 3-hydroxyvalerate precursors. Bioresour.

660

Technol. 2008, 99 (15), 6844–6851.

661

(42)

Doi, Y.; Tamaki, A.; Kunioka, M.; Soga, K. Production of copolyesters of 3-

662

hydroxybutyrate and 3-hydroxyvalerate by Alcaligenes eutrophus from butyric and

663

pentanoic acids. Appl. Microbiol. Biotechnol. 1988, 28 (4–5), 330–334.

664 665

(43)

Doi, Y.; Kunioka, M.; Nakamura, Y.; Soga, K. Biosynthesis of Copolyesters in Alcaligenes eutrophus H16 from13C-Labeled Acetate and Propionate. Macromolecules

ACS Paragon Plus Environment

34

Page 35 of 39 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

Biomacromolecules

666 667

1987, 20 (12), 2988–2991. (44)

Lefebvre, G.; Rocher, M.; Braunegg, G. Effects of Low Dissolved-Oxygen Concentrations

668

on Poly-(3-Hydroxybutyrate-co-3-Hydroxyvalerate) Production by Alcaligenes eutrophus.

669

Appl. Environ. Microbiol. 1997, 63 (3), 827–833.

670

(45)

671 672

Lee, W. S.; Chua, A. S. M.; Yeoh, H. K.; Ngoh, G. C. A review of the production and applications of waste-derived volatile fatty acids. Chem. Eng. J. 2014, 235, 83–99.

(46)

Atlić, A.; Koller, M.; Scherzer, D.; Kutschera, C.; Grillo-Fernandes, E.; Horvat, P.;

673

Chiellini, E.; Braunegg, G. Continuous production of poly([R]-3-hydroxybutyrate) by

674

Cupriavidus necator in a multistage bioreactor cascade. Appl. Microbiol. Biotechnol.

675

2011, 91 (2), 295–304.

676

(47)

677 678

Pederson, E. N.; McChalicher, C. W. J.; Srienc, F. Bacterial synthesis of PHA block copolymers. Biomacromolecules 2006, 7 (6), 1904–1911.

(48)

Hu, D.; Chung, A. L.; Wu, L. P.; Zhang, X.; Wu, Q.; Chen, J. C.; Chen, G. Q.

679

Biosynthesis and characterization of polyhydroxyalkanoate block copolymer P3HB-b-

680

P4HB. Biomacromolecules 2011, 12 (9), 3166–3173.

681

(49)

Tripathi, L.; Wu, L. P.; Meng, D.; Chen, J.; Chen, G. Q. Biosynthesis and characterization

682

of diblock copolymer of P(3-hydroxypropionate)-block-P(4-hydroxybutyrate) from

683

recombinant Escherichia coli. Biomacromolecules 2013, 14 (3), 862–870.

684

(50)

685 686

Tsuge, T. Fundamental factors determining the molecular weight of polyhydroxyalkanoate during biosynthesis. Polym. J. 2016, 48 (11), 1051–1057.

(51)

Castillo, T.; Flores, C.; Segura, D.; Espín, G.; Sanguino, J.; Cabrera, E.; Barreto, J.; Díaz-

ACS Paragon Plus Environment

35

Biomacromolecules 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

Page 36 of 39

687

Barrera, A.; Peña, C. Production of polyhydroxybutyrate (PHB) of high and ultra-high

688

molecular weight by Azotobacter vinelandii in batch and fed-batch cultures. J. Chem.

689

Technol. Biotechnol. 2017, 92 (7), 1809–1816.

690

(52)

691 692

Tan, D.; Wu, Q.; Chen, J.; Chen, G. Engineering Halomonas TD01 for the low-cost production of polyhydroxyalkanoates. Metab. Eng. 2014, 26, 34–47.

(53)

Hezayen, F. F.; Rehm, B. H.; Eberhardt, R.; Steinbüchel, a. Polymer production by two

693

newly isolated extremely halophilic archaea: application of a novel corrosion-resistant

694

bioreactor. Appl. Microbiol. Biotechnol. 2000, 54, 319–325.

695

(54)

Kulkarni, S. O.; Kanekar, P. P.; Nilegaonkar, S. S.; Sarnaik, S. S.; Jog, J. P. Production

696

and characterization of a biodegradable poly (hydroxybutyrate-co-hydroxyvalerate) (PHB-

697

co-PHV) copolymer by moderately haloalkalitolerant Halomonas campisalis MCM B-

698

1027 isolated from Lonar Lake, India. Bioresour. Technol. 2010, 101 (24), 9765–9771.

699

(55)

Kulkarni, S. O.; Kanekar, P. P.; Jog, J. P.; Patil, P. A.; Nilegaonkar, S. S.; Sarnaik, S. S.;

700

Kshirsagar,

701

hydroxyvalerate) (PHB-co-PHV) produced by Halomonas campisalis (MCM B-1027), its

702

biodegradability and potential application. Bioresour. Technol. 2011, 102 (11), 6625–

703

6628.

704

(56)

P.

R.

Characterisation

of

copolymer,

poly

(hydroxybutyrate-co-

Kulkarni, S. O.; Kanekar, P. P.; Jog, J. P.; Sarnaik, S. S.; Nilegaonkar, S. S. Production of

705

copolymer, poly (hydroxybutyrate-co-hydroxyvalerate) by Halomonas campisalis MCM

706

B-1027 using agro-wastes. Int. J. Biol. Macromol. 2015, 72, 784–789.

707

(57)

Laycock, B.; Halley, P.; Pratt, S.; Werker, A.; Lant, P. The chemomechanical properties

ACS Paragon Plus Environment

36

Page 37 of 39 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

Biomacromolecules

708 709

of microbial polyhydroxyalkanoates. Prog. Polym. Sci. 2014, 39 (2), 397–442. (58)

Li, S. Y.; Dong, C. L.; Wang, S. Y.; Ye, H. M.; Chen, G. Q. Microbial production of

710

polyhydroxyalkanoate block copolymer by recombinant Pseudomonas putida. Appl.

711

Microbiol. Biotechnol. 2011, 90 (2), 659–669.

712

(59)

Sudesh,

K.;

Abe,

H.;

Doi,

Y.

Synthesis,

structure

and

properties

of

713

polyhydroxyalkanoates: biological polyesters. Prog. Polym. Sci. 2000, 25 (10), 1503–

714

1555.

715

(60)

716 717

range of applications. J. Chem. Technol. … 2007, 82 (3), 233–247. (61)

718 719

Philip, S.; Keshavarz, T.; Roy, I. Polyhydroxyalkanoates: biodegradable polymers with a

Niaounakis, M. Chapter 2. Properties. In Biopolymers: Processing and Products; Elsevier, 2015; pp 79–116.

(62)

Pearce, R. P.; Marchessault, R. H. Melting and Crystallization in Bacterial Poly(beta-

720

hydroxyvalerate), PHV, and Blends with Poly(beta-hydroxybutyrate-co-hydroxyvalerate).

721

Macromolecules 1994, 27, 3869–3874.

722

(63)

Wang, Y.; Yamada, S.; Asakawa, N.; Yamane, T.; Yoshie, N.; Inoue, Y. Comonomer

723

compositional distribution and thermal and morphological characteristics of bacterial

724

poly(3-hydroxybutyrate-co-3-hydroxyvalerate)s with high 3-hydroxyvalerate content.

725

Biomacromolecules 2001, 2 (4), 1315–1323.

726

(64)

Misra, S. K.; Valappil, S. P.; Roy, I.; Boccaccini, A. R. Polyhydroxyalkanoate

727

(PHA)/inorganic

phase

composites

728

Biomacromolecules 2006, 7 (8), 2249–2258.

for

tissue

engineering

applications.

ACS Paragon Plus Environment

37

Biomacromolecules 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

729

(65)

Page 38 of 39

Steinbüchel, A.; Debzi, E. M.; Marchessault, R. H.; Timm, A. Synthesis and production of

730

poly(3-hydroxyvaleric acid) homopolyester by Chromobacterium violaceum. Appl.

731

Microbiol. Biotechnol. 1993, 39 (4–5), 443–449.

732

ACS Paragon Plus Environment

38

Page 39 of 39 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60

Biomacromolecules

84x32mm (300 x 300 DPI)

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