Bioresource Technology

The oleaginous yeast Rhodotorula toruloides is a promising host for sustainable bioproduction due to its capacity to naturally utilize xylose present in lignocellulosic biomass, an abundant and renewable resource. However, its xylose consumption pathway is still not completely understood. To better understand the potential limitations in xylose utilization in R. toruloides, heterologous xylose reductase from Scheffersomyces stipitis, together with the native and heterologous xylulokinases from three different microorganisms (Scheffersomyces stipitis, Candida intermedia, and Escherichia coli) were overexpressed solely and in combination. The overexpression of xylulokinases showed more significant improvements in terms of xylose consumption rate compared to the single overexpression of xylose reductase. When the heterologous xylulokinase from Escherichia coli was overexpressed, the specific xylose consumption rate was improved by 66% and the maximum specific growth rate by 30% compared to the parental strain. The xylose specific consumption rate increased by 146% and the maximum specific growth rate increased by 118% when heterologous genes for xylose reductase and xylulokinase from E. coli were overexpressed together. These results suggest that the low expression of xylulokinase in R. toruloides, which has been reported previously, could limit its sugar consumption, while supporting higher lipid accumulation in this yeast.

Lignocellulose biomass is one of the most abundant resources for sustainable biofuels. However, scaling up the biomass-to-biofuels conversion process for widespread usage is still pending. Bottlenecks during the process of enzymatic hydrolysis are the high cost of enzymes and the labor-intensive need for substrate-dependent enzyme mixtures. Current research efforts are therefore targeted at searching for or engineering lignocellulolytic enzymes of high efficiency. One way is to engineer multi-enzyme complexes that mimic the bacterial cellulosomal system, known to increase degradation efficiency up to 50-fold when compared to freely-secreted enzymes. However, these designer cellulosomes are instable and less efficient than wild type cellulosomes. Fungi cellulosomes discovered in recent years have significant differences from bacterial counterparts and hold great potential for industrial applications, both as designer cellulosomes and as additions to the enzymatic repertoire. Up to date, they are only found in a few anaerobic fungi. In this review, we extensively compared the degradation mechanisms in bacteria and fungi, and highlighted the essential gaps in applying these mechanisms in industrial applications. To better understand cellulosomes in microorganisms, we examined their sequences in 66,252 bacterial species and 823 fungal species and identified several bacterial species that are potentially cellulosome-producing. These findings act as a valuable resource in the biomass community for further proteomic and genetic sequence analysis. We also collated the current strategies of bioengineering lignocellulose degradation to suggest concepts that could be favorable for industrial usage.

During biofuels fermentation from pretreated lignocellulosic biomass, the strong toxicity of the lignocellulose hydrolysate is resulted from the synergistic effect of multiple lignocellulosic inhibitors, which far exceeds the sum of effects caused by every single inhibitor. Meanwhile, the synergistic effect is unclear and the underlying response mechanism of the industrial yeast towards the actual pretreated lignocellulose hydrolysate is still under exploration. Here, we employed an industrial S. cerevisiae for the transcriptomic analysis in two time points (early and late) of the lag phase under the corn stover hydrolysate stress. As investigation, the corn stover hydrolysate caused the accumulation of reactive oxygen species (ROS), damages of mitochondrial membrane and endoplasmic reticulum (ER) membrane in the industrial S. cerevisiae YBA_08 during the lag phase, especially these negative effects were more significant at the early lag phase. Based on the transcriptome profile, the industrial S. cerevisiae YBA_08 might recruit stress-related transcription factors (MSN4, STE12, SFL1, CIN5, COM2, MIG3, etc.) through the mitogen-activated protein kinase (MAPK)-signaling pathway to induce a transient G1/G2 arrest, and to activate defense bioprocesses like protectants metabolism, sulfur metabolism, glutaredoxin system, thioredoxin system, heat shock proteins chaperone and oxidoreductase detoxification, resisting those compounded stresses including oxidative stress, osmotic stress and structural stress. Surprisingly, this defense system might be accompanied with the transient repression of several bioprocesses like fatty acid metabolism, purine de novo biosynthesis and ergosterol biosynthesis. ImportanceThis research systematically demonstrated the lag phase response of an industrial yeast to the lignocellulosic hydrolysate in transcriptional level, providing a molecular fundament for understanding the synergistic effect of various lignocellulosic inhibitors and the regulatory mechanism of tolerance for industrial yeasts under this stress.

While investigating the conversion of cellulosic biomass to starch-like materials for industrial use, it was observed that the overexpression of native ADP-glucose pyrophosphorylase GlgC in Escherichia coli led to the formation of insoluble polysaccharide granules within the cytoplasm, occupying a large fraction of the cell volume, as well as causing an overall increase in cellular polysaccharide content. TEM microscopy revealed that the granules did not have the lamellar structure of starch, but rather an irregular, clustered structure. On starvation, cells overexpressing GlgC appeared unable to fully degrade their polysaccharide material and granules were still clearly visible in cultures after 8 days of starvation. Interestingly, the additional overexpression of the branching enzyme GlgB eliminated the production of granules and led to a further increase in cellular polysaccharides. GlgC is generally thought to be responsible for the rate-limiting step of glycogen synthesis. Our interpretation of these results is that excess GlgC activity may cause the elongation of glycogen chains to outpace the addition of side branches, allowing the chains of adjacent glycogen molecules to reach lengths at which they spontaneously intertwine, forming dense clusters that are largely inaccessible to the host. However, upon additional upregulation of the GlgB branching enzyme, the branching of the polysaccharide is able to keep speed with the synthesis of linear chains, eliminating the granule phenotype. This study suggests potential avenues for increasing bacterial polysaccharide production and recovery. ImportanceIn this work, the polysaccharide stores of Escherichia coli were altered through the addition of extra copies of the bacterias own polysaccharide synthesis genes. In this way, bacteria were created that produced over twice the level of storage polysaccharide as a control strain, in the form of a granule that could potentially facilitate easy harvest. Another form of mutant Escherichia coli was created that produced over seven times the normal level of storage polysaccharide, and also grew to higher cell densities in liquid culture. In addition to increasing our understanding of glycogen synthesis, it is proposed that similarly modified bacteria, grown on inexpensive waste materials, may be a useful source of starch-like polysaccharides for industrial or agricultural use. In particular, the use of cyanobacterial glycogen as a carbon source for biofuels has recently been gaining interest, and the work presented here may well be applicable in this field.

Lignin is a plant heteropolymer composed of phenolic subunits. Because of its heterogeneity and recalcitrance, the development of efficient methods for its valorization still remains an open challenge. One approach to utilize lignin is its chemical deconstruction into mixtures of monomeric phenolic compounds followed by biological funneling into a single product. Novosphingobium aromaticivorans DSM12444 has been previously engineered to produce 2-pyrone-4,6-dicarboxylic acid (PDC) from depolymerized lignin by simultaneously metabolizing multiple aromatics through convergent routes involving the intermediates 3-methoxygallic acid (3-MGA) and protocatechuic acid (PCA). We investigated enzymes predicted to be responsible for O-demethylation and oxidative aromatic ring opening, two critical reactions involved in the metabolism of phenolics compounds by N. aromaticivorans. The results showed the involvement of DesA in O-demethylation of syringic and vanillic acids, LigM in O-demethylation of vanillic acid and 3-MGA, and a new O-demethylase, DmtS, in the conversion of 3-MGA into gallic acid (GA). In addition, we found that LigAB was the main aromatic ring opening dioxygenase involved in 3-MGA, PCA, and GA metabolism, and that a previously uncharacterized dioxygenase, LigAB2, had high activity with GA. Our results indicate a metabolic route not previously identified in N. aromaticivorans that involves O-demethylation of 3-MGA to GA. We predict this pathway channels [~]15% of the carbon flow from syringic acid, with the rest following ring opening of 3-MGA. The new knowledge obtained in this study allowed for the creation of an improved engineered strain for the funneling of aromatic compounds that exhibits stoichiometric conversion of syringic acid into PDC. IMPORTANCEFor lignocellulosic biorefineries to effectively contribute to reduction of fossil fuel use, they need to become efficient at producing chemicals from all major components of plant biomass. Making products from lignin will require engineering microorganisms to funnel multiple phenolic compounds to the chemicals of interest, and N. aromaticivorans is a promising chassis for this technology. The ability of N. aromaticivorans to efficiently and simultaneously degrade many phenolic compounds may be linked to having functionally redundant aromatic degradation pathways and enzymes with broad substrate specificity. A detailed knowledge of aromatic degradation pathways is thus essential to identify genetic engineering targets to maximize product yields. Furthermore, knowledge of enzyme substrate specificity is critical to redirect flow of carbon to desired pathways. This study described an uncharacterized pathway in N. aromaticivorans and the enzymes that participate in this pathway, allowing the engineering of an improved strain for production of PDC from lignin.

Zymomonas mobilis is a promising bacterial host for biofuel production but further improvement has been hindered because some aspects of its metabolism remain poorly understood. For example, one of the main byproducts generated by Z. mobilis is acetate but the pathway for acetate production is unknown. Acetaldehyde oxidation has been proposed as the major source of acetate and an acetaldehyde dehydrogenase was previously isolated from Z. mobilis via activity guided fractionation, but the corresponding gene has never been identified. We determined that the locus ZMO1754 (also known as ZMO_RS07890) encodes an NADP+-dependent acetaldehyde dehydrogenase that is responsible for acetate production by Z. mobilis. Deletion of this gene from the chromosome resulted in a growth defect in oxic conditions, suggesting that acetaldehyde detoxification is an important role of acetaldehyde dehydrogenase. The deletion strain also exhibited a near complete abolition of acetate production, both in typical laboratory conditions and during lignocellulosic hydrolysate fermentation. Our results show that ZMO1754 encodes the major acetaldehyde dehydrogenase in Z. mobilis and we therefore rename the gene aldB based on functional similarity to the Escherichia coli acetaldehyde dehydrogenase. ImportanceBiofuel production from non-food crops is an important strategy for reducing carbon emissions from the transportation industry but it has not yet become commercially viable. An important avenue to improve biofuel production is to enhance the characteristics of fermentation organisms by genetic engineering. To make genetic modifications successful, we must gain sufficient information about the genome and metabolism of the organism to enable rational design and engineering. Here, we improved understanding of Zymomonas mobilis, a promising biofuel producing bacterium, by identifying a metabolic pathway and associated gene that lead to byproduct formation. This information may be used in the future for genetic engineering to reduce byproduct formation during biofuel production.

Microalgae cultivation, and phycoremediation, can be a polishing step in wastewater treatment. Depending on the stream utilized for microalgal cultivation, biomass can be contaminated with considerable quantities of heavy metals and xenobiotics. Given the economic value of microalgae bioproducts, we suggest coupling anaerobic fermentation with microalgae mixotrophic growth. Cheese whey, a product from cheese production, has a 2022 forecast production of 160.7 million m3 year-1 in which about 66.5 million m3 y-1 is used as animal feed, fertilizers or illegally discharged causing eutrophication. Anaerobic fermentation of cheese whey produces volatile fatty acids (VFAs) such as acetate which serves as an organic carbon source for photoorganoheterotrophic microalgal biomass growth. Our work selected three organic sources derived from cheese whey: 40% demineralized whey powder (WPC40), lactose, and acetate. In photolitoautotrophic conditions, green phototrophic growth was successful. In batch tests, acetate was the best organic carbon source among photoorganoheterotrophs with a higher yield of 1.15 mg VSS mg Carbon-1 (C) in anaerobic conditions. Also, acetate uptake was thought to be via the glyoxylate cycle. When upscaling the experiment in a chemostat, a lower dilution rate of 0.17 d-1 was more suitable for green photoorganoheterotrophs selection, as they were not washed out in the process. These findings show that acetate uptake by microalgae in mixotrophic regimes must be better understood as well as reinforce the advantages of coupling microalgal biomass growth with cheese whey acidogenic fermentation, avoiding contaminations as in phycoremediation processes and fully valorizing cheese whey. Graphical abstract O_FIG O_LINKSMALLFIG WIDTH=200 HEIGHT=150 SRC="FIGDIR/small/563819v1_ufig1.gif" ALT="Figure 1"> View larger version (28K): org.highwire.dtl.DTLVardef@16658c0org.highwire.dtl.DTLVardef@4ce591org.highwire.dtl.DTLVardef@73b8b2org.highwire.dtl.DTLVardef@162eef9_HPS_FORMAT_FIGEXP M_FIG C_FIG

With the increasing demand for sustainably produced renewable resources, it is important to look towards microorganisms capable of producing bioproducts such as biofuels and bioplastics. Though many systems for bioproduct production are well documented and tested in model organisms, it is essential to look beyond to non-model organisms to expand the field and take advantage of metabolically versatile strains. This investigation centers on Rhodopseudomonas palustris TIE-1, a purple, non-sulfur autotrophic, and anaerobic bacterium capable of producing bioproducts that are comparable to their petroleum-based counterparts. To induce bioplastic overproduction, genes that might have a potential role in the PHB biosynthesis such as the regulator, phaR, and phaZ known for its ability to degrade PHB granules were deleted using markerless deletion. Mutants in pathways that might compete with polyhydroxybutyrate (PHB) production such as glycogen and nitrogen fixation previously created to increase n-butanol production by TIE-1 were also tested. In addition, a phage integration system was developed to insert RuBisCO (RuBisCO form I and II genes) driven by a constitutive promoter PaphII into TIE- 1 genome. Our results show that deletion of the phaR gene of the PHB pathway increases PHB productivity when TIE-1 was grown photoheterotrophically with butyrate and ammonium chloride (NH4Cl). Mutants unable to make glycogen or fix dinitrogen gas show an increase in PHB productivity under photoautotrophic growth conditions with hydrogen. In addition, the engineered TIE-1 overexpressing RuBisCO form I and form II produces significantly more polyhydroxybutyrate than the wild type under photoheterotrophy with butyrate and photoautotrophy with hydrogen. Inserting RuBisCO genes into TIE-1 genome is a more effective strategy than deleting competitive pathways to increase PHB production in TIE-1. The phage integration system developed for TIE-1 thus creates numerous opportunities for synthetic biology in TIE-1.

Acetogenic bacteria play an important role in various biotechnological processes, because of their chemolithoautotrophic metabolism converting carbon dioxide with molecular hydrogen (H2) as electron donor into acetate. As the main factor limiting acetogenesis is often H2, insights into the H2 consumption kinetics of acetogens is required to assess their potential in biotechnological processes. In this study, initial H2 consumption rates at a range of different initial H2 concentrations were measured for three different acetogens. Interestingly, for all three strains, H2 consumption was found to follow first-order kinetics, i.e. the H2 consumption rate increased linearly with the dissolved H2 concentration, up to almost saturated H2 levels (600 {micro}M). This is in contrast with Monod kinetics and low half-saturation concentrations, which have commonly been assumed for acetogens. The obtained biomass specific first-order rate coefficients (k1X) were further validated by comparison with values obtained by fitting first-order kinetics on previous time-course experimental results. The latter method was also used to determine the k1X value of five additional acetogens strains. Biomass specific first-order rate coefficients were found to vary up to six-fold, with the highest k1X for Acetobacterium wieringae and the lowest for Sporomusa sphaeroides. Overall, our results demonstrate the importance of the dissolved H2 concentration to understand the rate of acetogenesis in biotechnological systems.

Biogas plants serve as hubs for the collection and utilization of highly nutritious waste streams from households and agriculture. However, their outputs (biogas and digestate) are of relatively low economic value. Here, we explore the co-production of yeast single cell protein, a potentially valuable feed ingredient for aquaculture and other animal producing industries, with biogas on substrate collected at a co-digestion biogas plant, using three yeast species well suited for this purpose (Wickerhamomyces anomalus, Pichia kudriavzevii, and Blastobotrys adeninivorans). All yeasts grew rapidly on the substrate, yielding 7.0-14.8 g l-1 biomass after 12-15 The biomass crude protein contents were 22.6-32.7 %, with relatively favorable amino acid compositions mostly deficient in methionine and cysteine. Downstream biomethanation potential was significantly different between yeast species, with the highest product yielding species (Blastobotrys adeninivorans) also yielding the highest biomethanation potential.\n\nHighlightsO_LIAll yeasts grew well on the biogas substrate, with high growth rates.\nC_LIO_LIProduced biomass was of high nutritional value for use in fish feed formulations.\nC_LIO_LIDownstream effects on methane potential were strain-dependent.\nC_LIO_LIYeast biomass may be a viable biogas co-product.\nC_LI

Polyhydroxyalkanoates (PHAs) have emerged as an ecologically friendly alternative to conventional polyesters. In this study, we present a comprehensive analysis of the genomic and phenotypic characteristics of three non-model thermophilic bacteria known for their ability to produce PHAs: Schlegelella aquatica LMG 23380T, Caldimonas thermodepolymerans DSM 15264, and C. thermodepolymerans LMG 21645 accompanied by a comparison with the type strain C. thermodepolymerans DSM 15344T. We have assembled the first complete genomes of these three bacteria and performed the structural and functional annotation. This analysis has provided valuable insights into the biosynthesis of PHAs and has allowed us to propose a comprehensive scheme for the carbohydrate metabolism in the studied bacteria. Through phylogenomic analysis, we have confirmed the synonymity between Caldimonas and Schlegelella genera, and further demonstrated that S. aquatica and S. koreensis, currently classified as orphan species, belong to the Caldimonas genus. SummaryThe genomic and phenotypic analysis of Schlegelella aquatica LMG 23380T and Caldimonas thermodepolymerans DSM 15264 and LMG 21645 sheds light on the production of sustainable polyesters known as polyhydroxyalkanoates (PHAs). The genome assembly and functional annotation highlight key genes related to PHA production and other important traits. Notably, C. thermodepolymerans stands out with its unique xyl operon, making it a highly promising candidate for biotechnological PHA production from xylose-rich lignocellulosic resources. The study emphasizes the importance of a polyphasic approach combining genotypic and phenotypic analyses in prokaryotic taxonomy, emphasizing the need for exploration in the genomic era. By uncovering the key traits of these bacteria, this research opens new horizons towards sustainable production of environmentally friendly polyesters.

Pseudomonas putida have emerged as promising biocatalysts for the conversion of sugars and aromatics obtained from lignocellulosic biomass. Understanding the role of carbon catabolite repression (CCR) in these strains is critical to optimize biomass conversion to fuels and chemicals. The CCR functioning in P. putida M2, a strain capable of consuming both hexose and pentose sugars as well as aromatics, was investigated by cultivation experiments, proteomics, and CRISPRi-based gene repression. Strain M2 co-utilized sugars and aromatics simultaneously; however, during co-cultivation with glucose and phenylpropanoid aromatics (p-coumarate and ferulate), intermediates (4-hydroxybenzoate and vanillate) accumulated, and substrate consumption was incomplete. In contrast, xylose-aromatic consumption resulted in transient intermediate accumulation and complete aromatic consumption, while xylose was incompletely consumed. Proteomics analysis revealed that glucose exerted stronger repression than xylose on the aromatic catabolic proteins. Key glucose (Eda) and xylose (XylX) catabolic proteins were also identified at lower abundance during co-cultivation with aromatics implying simultaneous catabolite repression by sugars and aromatics. Downregulation of crc via CRISPRi led to faster growth and uptake of glucose and p-coumarate in the CRISPRi strains compared to the control while no difference was observed on xylose + p-coumarate. The increased abundance of the Eda and amino acids biosynthesis proteins in the CRISPRi strain further supported these observations. Lastly, small RNAs (sRNAs) sequencing results showed that CrcY and CrcZ homologues levels in M2, previously identified in P. putida strains, were lower under strong CCR (glucose + p-coumarate) condition compared to when repression was absent (p-coumarate or glucose only). IMPORTANCEA newly isolated Pseudomonas putida strain, P. putida M2, can utilize both hexose and pentose sugars as well as aromatics making it a promising host for the valorization of lignocellulosic biomass. Pseudomonads have developed a regulatory strategy, carbon catabolite repression, to control the assimilation of carbon sources in the environment. Carbon catabolite repression may impede the simultaneous and complete metabolism of sugars and aromatics present in lignocellulosic biomass and hinder the development of an efficient industrial biocatalyst. This study provides insight into the cellular physiology and proteome during mixed-substrate utilization in P. putida M2. The phenotypic and proteomics results demonstrated simultaneous catabolite repression in the sugar-aromatic mixtures while the CRISPRi and sRNA sequencing demonstrated the potential role of the crc gene and small RNAs in carbon catabolite repression.

Ethanol production from renewable cellulosic materials is a globally significant research area. However, the high temperatures and acetic acid generated during cellulose pretreatment can inhibit Saccharomyces cerevisiae growth, reducing ethanol yields. This study investigates the impact of glutaredoxin family genes (GRXs) over-expression on S. cerevisiae cell growth and fermentation performance under thermal and acetic acid stress. Engineered strains overexpressing GRX1, GRX2, and GRX5 demonstrated enhanced growth at 42{degrees}C, while those overexpressing GRX1, GRX2, GRX6, and GRX7 showed improved growth at 1 g/L acetic acid. These results suggest that GRX over-expression can remediate S. cerevisiae, potentially accelerating advancements in green biomanufacturing.

PHB (poly-hydroxy-butyrate) represents a promising bioplastic variety with good biodegradation properties. Furthermore, PHB can be produced completely carbon-neutral when synthesized in the natural producer cyanobacterium Synechocystis sp. PCC 6803. This model strain has a long history of various attempts to further boost its low amounts of produced intracellular PHB of ~15 % per cell-dry-weight (CDW). We have created a new strain that lacks the regulatory protein PirC (gene product of sll0944), which causes a rapid conversion of the intracellular glycogen pools to PHB under nutrient limiting conditions. To further improve the intracellular PHB content, two genes from the PHB metabolism, phaA and phaB from the known production strain Cupriavidus necator, were introduced under the regime of the strong promotor PpsbA2. The created strain, termed PPT1 ({Delta}sll0944-REphaAB), produced high amounts of PHB under continuous light as well under day-night rhythm. When grown in nitrogen and phosphor depleted medium, the cells produced up to 63 % / CDW. Upon the addition of acetate, the content was further increased to 81 % / CDW. The produced polymer consists of pure PHB, which is highly isotactic. The achieved amounts were the highest ever reported in any known cyanobacterium and demonstrate the potential of cyanobacteria for a sustainable, industrial production of PHB.

Slow cell growth and low biomass yields are hurdles for gas fermentation by acetogens. Microbial electrosynthesis (MES) utilizes acetogens as biocatalysts to reduce CO2 and produce commodity chemicals using electricity. However, limited electron supply in a bioelectrochemical system (BES) aggravates the poor cell growth of acetogens resulting in low productivities. Formate is a soluble C1 feedstock that can be produced by CO2 reduction (1). Thus, assimilation of formate can unburden the amount of electrons required for MES. Acetobacterium woodii posseses multiple pyruvate formate lyase (PFL) genes that are upregulated during formatotrophic growth. In this study, Clostridium ljugdahlii was engineered to heterologously express a pfl geneset of A. woodii to increase the cell growth of C. ljungdahlii during microbial electrosynthesis. Different combinations of pfl A and pfl B from A. woodii were tested in C. ljungdahlii to find the best working combination under control of Pfdx-riboswitch expression system. Expression of pfl B1 and pflA of A. woodii showed higher maximum OD of C. ljugdahlii under H2:CO2 condition with supplementation of 80 mM sodium formate. More than 40 mM of sodium formate caused significantly longer lag phase but the lag phase could be shortened after adaptation in 80 mM of sodium formate. At the end, the engineered strain showed improved cell growth (ODmax 0.22 {+/-} 0.05) and acetate production (21.8 {+/-} 5.6 mM) during microbial electrosynthesis compared to the control strain (ODmax 0.10 {+/-}0.06 and 10.2 {+/-}2.5 mM acetate). These results will be useful for strain development for microbial electrosynthesis, as well as gas fermentation. HighlightsO_LIDifferent combinations of pyruvate formate lyases (pfl Bs) and pyruvate formate lyase acting enzymes (pfl As) from Acetobacterium woodii were tested to improve the cell growth of Clostridium ljungdahlii during gas fermentation and microbial electrosynthesis C_LIO_LIHeterologous expression of pfl B1 and pfl A using riboswitch expression system improved cell growth of C. ljungdahlii under H2:CO2 condition, even without inducer and formate supplementation. C_LIO_LIHigh concentraton of sodium formate caused longer lag phase, which was shortened by adaptation when pfl from A. woodii was heterologously expressed. C_LIO_LICell growth and acetate production of the engineered C. ljungdahlii strain improved during microbial electrosynthesis C_LI

A plethora of studies have focused on improvements of xylitol production. The challenges of establishing a biotechnological route for the industrial production of this sugar have been explored using different microorganisms and renewable feedstock. Nevertheless, sugarcane biomass has been neglected as the pentose source for xylitol production using Saccharomyces cerevisiae. Therefore, here we investigate the use of an industrial S. cerevisiae strain for xylitol production in batch fermentation of non-detoxified sugarcane straw hydrolysate, envisioning the diversification of the current infrastructure used for second-generation bioethanol production from the same lignocellulosic material. In order to optimize the xylose conversion in a non-fed cultivation system, guidelines in cell inoculum and medium supplementation are suggested, as well as the first attempt to use electro-fermentation for this purpose. Accordingly, our results show that the increase in initial cell density and hydrolysate supplementation allows a xylitol production of 19.24 {+/-} 0.68 g/L, representing 0,132 g/L.h productivity.

Chlamydomonas incerta, a genetically close relative of the model green alga Chlamydomonas reinhardtii, shows significant potential as a host for recombinant protein expression. Because of the close genetic relationship between C. incerta and C. reinhardtii, this species offers an additional reference point for advancing our understanding of photosynthetic organisms, and also provides a potential new candidate for biotechnological applications. This study investigates C. incertas capacity to express three recombinant proteins: the fluorescent protein mCherry, the hemicellulose-degrading enzyme xylanase, and the plastic-degrading enzyme PHL7. We have also examined the capacity to target protein expression to various cellular compartments in this alga, including the cytosol, secretory pathway, cytoplasmic membrane, and cell wall. When compared directly with C. reinhardtii, C. incerta exhibited a distinct but notable capacity for recombinant protein production. Cellular transformation with a vector encoding mCherry revealed that C. incerta produced approximately 3.5 times higher fluorescence levels and a 3.7-fold increase in immunoblot intensity compared to C. reinhardtii. For xylanase expression and secretion, both C. incerta and C. reinhardtii showed similar secretion capacities and enzymatic activities, with comparable xylan degradation rates, highlighting the industrial applicability of xylanase expression in microalgae. Finally, C. incerta showed comparable PHL7 activity levels to C. reinhardtii, as demonstrated by the in vitro degradation of a polyester polyurethane suspension, Impranil(R) DLN. Finally, we also explored the potential of cellular fusion for the generation of genetic hybrids between C. incerta and C. reinhardtii as a means to enhance phenotypic diversity and augment genetic variation. We were able to generate genetic fusion that could exchange both the recombinant protein genes, as well as associated selectable marker genes into recombinant offspring. These findings emphasize C. incertas potential as a robust platform for recombinant protein production, and as a powerful tool for gaining a better understanding of microalgal biology. GRAPHICAL ABSTRACT O_FIG O_LINKSMALLFIG WIDTH=200 HEIGHT=126 SRC="FIGDIR/small/618925v1_ufig1.gif" ALT="Figure 1"> View larger version (25K): org.highwire.dtl.DTLVardef@173d398org.highwire.dtl.DTLVardef@148ad36org.highwire.dtl.DTLVardef@63b5e9org.highwire.dtl.DTLVardef@3be081_HPS_FORMAT_FIGEXP M_FIG C_FIG

The primary challenge in utilizing palm kernel meal (PKM, an agricultural by-product) as non- ruminant livestock feed is its high fibre content, predominantly in the form of mannan. Microbial fermentation offers an economically favourable alternative to enzyme supplementation for breaking down fibre in lignocellulosic biomass. In a recent study, we have isolated and characterized an undomesticated strain (Bacillus subtilis F6) that is able to secrete mannanase. In this work, the mannanase production was substantially improved by optimizing multiple regulatory elements controlling the mannanase expression. Mannanase GmuG, sourced from B. subtilis F6 and verified for its hydrolytic activity on PKM fibre, was expressed using a replicative plasmid (pBE-S). The recombinant strain of B. subtilis F6 exhibited 1.9-fold increase in the mannanase activity during solid-state fermentation. Optimization of signal peptide and ribosome binding site further enhanced mannanase activity by 3.1-fold. Subsequently, promoter screening based on highly transcribed genes in B. subtilis F6 resulted in a significant 5.4-fold improvement in mannanase activity under the nprE promoter. The nprE promoter was further refined by eliminating specific transcription factor binding sites, enhancing the mannanase activity further by 1.8-fold. Notably, a substantial 35-40% reduction in PKM fibre content was observed after 30 h of fermentation using the recombinant strains. Lastly, the highest mannanase-producing strain was examined for scaled-up fermentation. The impacts of fermentation on fibre and protein contents, as well as the surface morphology of PKM, were analysed. The outcomes of this study offer an efficient method for robust mannanase expression in B. subtilis and its potential application in the biotransformation of PKM and other mannan-rich bioresources for improved feed utilization. Graphical abstract O_FIG O_LINKSMALLFIG WIDTH=200 HEIGHT=83 SRC="FIGDIR/small/602432v1_ufig1.gif" ALT="Figure 1"> View larger version (17K): org.highwire.dtl.DTLVardef@10fbb9corg.highwire.dtl.DTLVardef@1e619fborg.highwire.dtl.DTLVardef@1b3bc0corg.highwire.dtl.DTLVardef@fec816_HPS_FORMAT_FIGEXP M_FIG C_FIG

Biodegradable plastics are urgently needed to replace petroleum-derived polymeric materials and prevent their accumulation in the environment. To this end, we isolated and characterized a halophilic and alkaliphilic bacterium from the Great Salt Lake in Utah. The isolate was identified as a Halomonas species and designated "CUBES01". Full-genome sequencing and genomic reconstruction revealed the unique genetic traits and metabolic capabilities of the strain, including the common polyhydroxyalkanoate (PHA) biosynthesis pathway. Fluorescence staining identified intracellular polyester granules that accumulated predominantly during the strains exponential growth, a feature rarely found among natural PHA producers. CUBES01 was found to metabolize a range of renewable carbon-feedstocks, including glucosamine and acetyl-glucosamine, as well as sucrose, glucose, fructose, and further also glycerol, propionate, and acetate. Depending on the substrate, the strain accumulated up to [~]60% of its biomass [dry w/w] in poly(3-hydroxbutyrate), while reaching a doubling time of 1.7 h at 30{whitebullet}C and an optimum osmolarity of 1 M sodium chloride and a pH of 8.8. The physiological preferences of the strain may not only enable long-term aseptic cultivation but can also facilitate the release of intracellular products through osmolysis. Development of a minimal medium also allowed the estimation of maximum PHB production rates, which were projected to exceed 5 gPHB/h. Finally, also the genetic tractability of the strain was assessed in conjugation experiments: two orthogonal plasmid-vectors were stable in the heterologous host, thereby opening the possibility of genetic engineering through the introduction of foreign genes. IMPORTANCEThe urgent need for renewable replacements for synthetic materials may be addressed through microbial biotechnology. To simplify the large-scale implementation of such bio-processes, robust cell factories that can utilize sustainable and widely available feedstocks are pivotal. To this end, non-axenic growth-associated production could reduce operational costs and enhance biomass productivity, thereby improving commercial competitiveness. Another major cost factor is downstream processing. Especially in the case of intracellular products, such as bio-polyesters. Simplified cell-lysis strategies could also further improve economic viability.

Medium-chain carboxylates are used in various industrial applications. These chemicals are typically extracted from palm oil, which is deemed not sustainable. Recent research has focused on microbial chain elongation using reactors to produce medium-chain carboxylates, such as n-caproate (C6) and n-caprylate (C8), from organic substrates such as wastes. Even though the production of n-caproate is relatively well-characterized, bacteria and metabolic pathways that are responsible for n-caprylate production are not. Here, three 5-L reactors with continuous membrane-based liquid-liquid extraction (i.e., pertraction) were fed ethanol and acetate and operated for an operating period of 234 days with different operating conditions. Metagenomic and metaproteomic analyses were employed. n-Caprylate production rates and reactor microbiomes differed between reactors even when operated similarly due to differences in H2 and O2 between the reactors. The complete reverse {beta}-oxidation pathway was present and expressed by several bacterial species in the Clostridia class. Several Oscillibacter spp., including Oscillibacter valericigenes, were positively correlated with n-caprylate production rates, while Clostridium kluyveri was positively correlated with n-caproate production. Pseudoclavibacter caeni, which is a strictly aerobic bacterium, was abundant across all the operating periods, regardless of n-caprylate production rates. This study provides insight into microbiota that are associated with n-caprylate production in open-culture reactors and provides ideas for further work. ImportanceMicrobial chain elongation pathways in open-culture biotechnology systems can be utilized to convert organic waste and industrial side streams into valuable industrial chemicals. Here, we investigated the microbiota and metabolic pathways that produce medium-chain carboxylates, including n-caproate (C6) and n-caprylate (C8), in reactors with in-line product extraction. Although the reactors in this study were operated similarly, different microbial communities dominated and were responsible for chain elongation. We found that different microbiota were responsible for n-caproate or n-caprylate production, and this can inform engineers on how to operate the systems better. We also observed which changes in operating conditions steered the production toward and away from n-caprylate, but more work is necessary to ascertain a mechanistic understanding that could be predictive. This study provides pertinent research questions for future work.