Genome and metabolic engineering in non-conventional yeasts: Current advances and applications.

Microbial production of chemicals and proteins from biomass-derived and waste sugar streams is a rapidly growing area of research and development. While the model yeast Saccharomyces cerevisiae is an excellent host for the conversion of glucose to ethanol, production of other chemicals from alternative substrates often requires extensive strain engineering. To avoid complex and intensive engineering of S. cerevisiae, other yeasts are often selected as hosts for bioprocessing based on their natural capacity to produce a desired product: for example, the efficient production and secretion of proteins, lipids, and primary metabolites that have value as commodity chemicals. Even when using yeasts with beneficial native phenotypes, metabolic engineering to increase yield, titer, and production rate is essential. The non-conventional yeasts Kluyveromyces lactis, K. marxianus, Scheffersomyces stipitis, Yarrowia lipolytica, Hansenula polymorpha and Pichia pastoris have been developed as eukaryotic hosts because of their desirable phenotypes, including thermotolerance, assimilation of diverse carbon sources, and high protein secretion. However, advanced metabolic engineering in these yeasts has been limited. This review outlines the challenges of using non-conventional yeasts for strain and pathway engineering, and discusses the developed solutions to these problems and the resulting applications in industrial biotechnology.

Introduction

The microbial production of fuels and chemicals from biomass and other renewable carbon sources is an attractive alternative to petroleum-derived products. One of the largest scale example of this is ethanol production by the yeast Saccharomyces cerevisiae— in 2015, over 25 billion gallons were produced worldwide from starch, waste sugar streams, and biomass-derived sugars (www.afdc.energy.gov/data/10331). S. cerevisiae is the organism of choice because of its high rate of production and tolerance to ethanol titers upwards of 120 g L−1 [1], [2]. These phenotypes, among others, have led to the widespread study of S. cerevisiae and its development as a model eukaryotic host for chemical biosynthesis. A valuable approach to metabolic engineering is identifying organisms with desirable phenotypes and developing new synthetic biology tools to enhance these phenotypes. Bioethanol production in S. cerevisiae is a good example of this, and illustrates the potential of identifying other hosts and phenotypes to synthesize bioproducts other than ethanol. A number of examples of this strategy already exist in industry, where non-conventional yeasts with unique and advantageous phenotypes are used to produce proteins, lipids, and commodity chemicals. Metabolic engineering in these yeasts is, however, more challenging in comparison with S. cerevisiae, because less is known about their metabolism and genomics, and advanced genetic engineering tools are limited.

In this review, we focus on six non-conventional yeasts (Table 1): Kluyveromyces lactis, K. marxianus, Scheffersomyces (Pichia) stipitis, Yarrowia lipolytica, Hansenula polymorpha, and Pichia pastoris. In contrast to S. cerevisiae, these yeasts are Crabtree negative and favor respiration over fermentation; phenotypes that are particularly useful for protein production as well as the biosynthesis of chemicals other than ethanol [3]. K. lactis is discussed here because of its capacity to metabolize inexpensive substrates such as waste whey and because of its use as a host for heterologous protein production in the food, feed, and pharmaceutical industries [4]. The Kluyveromyces species K. marxianus is also industrially relevant because of its wide substrate spectrum, fast growth characteristics, and thermotolerance to ∼50 °C [5], [6]. Native strains of K. marxianus are also known to synthesize ethyl acetate at rates above 2 g L−1 h−1 in aerated bioreactors [7], [8]. S. stipitis is capable of fermenting xylose at high rates compared to other yeasts and has been widely studied for ethanol production from biomass-derived sugars [9], [10]. Y. lipolytica is a well-studied oleaginous yeast and has attracted interest due to its ability to synthesize and accumulate high levels of intracellular lipids [11], [12], [13]. The methylotrophic yeast H. polymorpha has been studied as a model system for peroxisome function as well as for its methanol and nitrate assimilation pathways [14], [15]. Significant efforts have gone into heterologous protein production in H. polymorpha due to its efficient secretion pathways, effective glycosylation machinery, and tightly controlled expression systems [16]. H. polymorpha is also thermotolerant to temperatures comparable to K. marxianus and can assimilates various substrates, thus making it a potential alternative host for ethanol production [17]. The methylotrophic yeast P. pastoris has similar protein secretion and glycosylation capabilities to H. polymorpha and has been widely used for heterologous protein production [18]. Its capacity to grow to extremely high cell densities and high capacity for membrane protein expression also provide inherent advantages over other yeast hosts [19], [20].

Table 1

Overview of non-conventional yeast species, their industrially-relevant phenotypes, common uses in biotechnology, and comparison with S. cerevisiae.

Yeast	Beneficial Phenotype	Products	Reference
K. lactis	High protein secretionGrowth on lactose	Proteins for food and feed industryPharmaceutical enzymes	[4]
K. marxianus	ThermotoleranceFast growth characteristicsHigh ethyl acetate productionGrowth on a range of sugars	Ethanol and volatile acetate esters	[5]
S. stipitis	High ethanol production from xylose	Ethanol fermentation from biomass derived carbohydrates	[21]
Y. lipolytica	Efficient production of lipidsGrowth on glycerol and alkanes	Lipids and oleochemicals	[12]
H. polymorpha	ThermotoleranceTightly regulated expression systemBeneficial glycosylation for therapeutics	Heterologous proteinHigh temperature ethanol fermentation	[17], [18]
P. pastoris	Tightly regulated expression systemHigh cell density on minimal mediaBeneficial glycosylation for therapeuticsEfficient production of membrane proteins	Pharmaceuticals and industrial enzymes	[18]
S. cerevisiae	High ethanol productionHigh HR capacityWell known genomics and physiologyAdvanced synthetic biology tools	Ethanol in fermented beverages and as biofuelCommodity and specialty chemicalsPharmaceuticals	[2], [22]

Despite these many advantages, metabolic engineering of non-conventional yeasts is limited by a lack of sophisticated genome editing tools and an incomplete understanding of their genetics, metabolism, and cellular physiology. In this review, we discuss the challenges and solutions that have arisen in engineering non-conventional yeasts for metabolic engineering and synthetic biology applications. We begin our review with a discussion of the challenges to genetic engineering, followed by a discussion of strategies for improving genome and pathway engineering. Finally, we discuss representative examples of metabolic engineering in each of the selected yeasts. While the presented examples are not exhaustive, they are exemplative of current and past research efforts that exploit the yeasts' advantageous phenotypes. Reviews that provide comprehensive discussions on engineering each of the non-conventional yeasts described here are available elsewhere [4], [12], [17], [21], [23], [24].

Genetic engineering challenges in non-conventional yeasts

A basic requirement for metabolic engineering is the ability to express a gene (native or heterologous) from an expression cassette. Most strategies for heterologous gene expression in yeasts utilize auxotrophic markers to provide selective pressure for the maintenance of heterologous DNA containing the expression cassette (Fig. 1). Gene expression of native or heterologous genes is most often accomplished through episomal vectors or by integration of the gene(s)-of-interest into the host genome. In S. cerevisiae, transformation and expression from replicating plasmids is widely used due to the availability of stable and high copy number vectors [25], [26]. In non-conventional yeasts, options for stable plasmids are more limited. Plasmids are initially generated by combining centromeric regions of the organism’s genome and autonomous replicating sequences with a selectable auxotrophic marker [27]. While functional plasmids are available for most non-conventional yeasts, they tend to be low copy number and show variable expression across cells in a single population, an effect that is due to imperfect partitioning of plasmids upon cell division [28], [29].

Fig. 1

Schematic diagram of the generation and utilization of auxotrophic markers for engineering yeast. Random mutagenesis of host DNA or homologous recombination of a cassette that inactivates an essential gene for nutrient synthesis can be used to produce stable auxotrophic strains. The presence of an auxotrophy allows more advanced genome editing and pathway engineering tools to be applied in the yeast species of interest. Shown here are 1) targeted and random integration using a selectable marker (bottom, left), 2) HisG/lacZ-mediated marker recovery (bottom, middle), 3) Cre-lox-mediated marker recovery (bottom, middle), and 4) Markerless editing by CRISPR-Cas9 (bottom, right).

The preferred strategy for heterologous gene expression in industrial strains is integration into the host's genome. Genomic integration leads to more homogenous expression levels across the population, increases the stability of the expression cassette over extended culture times, and eliminates the need for constant selection of a genetic marker [30]. Transformation with a linear DNA fragment containing an expression cassette and a selectable marker results in genomic integration in one of two ways: heterologous DNA is either incorporated into the genome at a random locus (often called illegitimate recombination [31]), or the cassette is targeted to a specific site in the genome by homology to the site of interest (Fig. 1). Both types of integrations are performed by native DNA repair pathways. Random integration proceeds through nonhomologous end-joining (NHEJ), while targeted integration occurs by homologous recombination (HR) [32]. Integration via HR is often preferred, because it enables control over the integration loci, avoids disrupting essential genes, and allows for integration into a site with a consistent expression profile [33]. Integration via HR can also be used to knockout native genes.

In S. cerevisiae, HR is the dominant DNA repair pathway. The high capacity for HR makes genome engineering relatively efficient and has facilitated the development of a wide range of in vivo DNA assembly tools [34], [35]. This is not the case in most other yeasts, where NHEJ is the favored DNA repair pathway and genome engineering by HR is inefficient. As a result, engineering of non-conventional yeasts is frequently accomplished by random integration. The random integration of the transformed expression cassette can lead to unwanted disruptions of open reading frames or other genomic elements. In addition, expression levels of heterologous cassettes have been shown to be highly dependent on the integration site, and so random integration can result in variable expression across transformants [33], [36].

An additional challenge to engineering multi-gene pathways is the limited number of viable selectable markers. To overcome this experimental challenge, researchers have developed several techniques for marker recovery (Fig. 1). The most commonly used systems are Cre-loxP, hisG, and lacZ [37], [38]. In these cases, the selectable marker (e.g., an antibiotic resistance gene or auxotrophic marker) is surrounded by hisG, lacZ, or loxP sequences. After genome integration of an expression or knockout cassette, the marker is excised by spontaneous HR or Cre recombinase activity. While the hisG and lacZ systems are effective, the Cre-loxP method is more common because hisG and lacZ systems require a counter-selection such as growth on media supplemented with 5-fluoroorotic acid (5-FOA) for URA3 excision [39], [40], [41], [42], [43]. While Cre-loxP systems are available for use in the non-conventional yeasts discussed in this review, this marker recovery technique does not solve the challenge of random, unknown integration sites that is problematic with illegitimate recombination.

Enhancing HR in non-conventional yeasts

A widely used strategy to enhance HR in non-conventional yeasts is disruption of genes essential for the NHEJ pathway, such as KU70 or KU80. K. lactis provides an early example of this strategy, where disruption of KU80 produced a strain capable of integrating heterologous DNA via HR at a rate of 97% [44]. Similarly, disruption of KU80 in S. stipitis resulted in an increase in the rate of HR-mediated integration of transformed linear donors [45]. In Y. lipolytica, disruption of KU70 or KU80 produced significant increases in HR rates, and allowed HR to occur with homology regions down to 50 bp [46], [47]. In H. polymorpha, KU80 knockout produced an increase in alcohol oxidase gene knockout rates (AOX2-8) from an average of 19% in the wildtype background to 76% in the KU80 deficient strain [48]. In P. pastoris, knockout of KU70 enabled HR rates as high as 90% [49]. A similar result was found in K. marxianus, where KU70 knockout increased HR rates to as high as 95% [50]. KU80 disruption in K. marxianus was similarly effective, with HR rates increasing to upwards of 70% [51].

A second strategy that has had success in increasing HR is cell cycle synchronization. Natively, the activity of the HR DNA repair pathway is dependent on cell cycle [52]. When a single copy of chromosomal DNA is present, as in G1 phase, NHEJ is favored. Genes required for HR tend to only be expressed during phases of the cell cycle when multiple copies of chromosomes are available, i.e., S phase and G2 phase. Cell cycle synchronization has been widely used for fundamental biochemistry studies, and a recent work took advantage of this strategy to stall cells in S phase with the intent of increasing HR [53]. By adding hydroxyurea to cultures undergoing exponential growth, the authors demonstrated that S phase stalling resulted in enhanced HR in Y. lipolytica, K. lactis, and P. pastoris.

An alternative strategy to achieve efficient HR is the introduction of a genomic double strand break (DSB) using a programmable endonuclease in the presence of a homologous repair template [54]. Due to the deleterious effects of DSBs on cell viability, native repair pathways attempt to repair the cut. If a repair template with adequate homology to the region flanking the break is present, the host may use the template as a donor for HR. This strategy has the added benefit of not requiring a selectable marker on the integrated DNA fragment. Several programmable tools exist for targeted DSB, including dimeric meganucleases, zinc finger nucleases, transcription activator-like effector nucleases (TALENs), and clustered regularly interspaced short palindromic repeats (CRISPR) and CRISPR-associated 9 (CRISPR-Cas9) [54]. The first three of these have primarily been developed and applied in S. cerevisiae, although TALENs were recently used in Y. lipolytica [55], [56]. CRISPR-Cas9, however, has been widely applied in non-conventional yeasts as described in the following section.

CRISPR-Cas9 genome editing and transcriptional control

In recent years, the application of CRISPR-Cas9 technology has revolutionized genome editing. Specifically, the type II CRISPR-Cas9 system from Streptococcus pyogenes has been widely adopted to enable targeted DSB generation in a wide number of organisms [57], [58]. Functional expression of CRISPR-Cas9 in yeast has two main requirements. First, a codon-optimized Cas9 expression cassette is generated, with a nuclear localization tag fused to its C-terminus. A nuclear localization tag is needed because S. pyogenes is a bacterium, and so unmodified Cas9 would localize to the cytosol in yeast. The second component of CRISPR-Cas9 systems (as commonly applied for genome editing) is a short (or single) guide RNA (sgRNA) [59]. The sgRNA has two main roles. The first 20 bp at the 5′ end are known as the spacer and are responsible for genome targeting through complementation to the desired locus. The sgRNA also contains a structural region encoded downstream of the spacer that facilitates the interaction of the sgRNA and Cas9. Upon formation of the CRISPR-Cas9 ribonucleoprotein, the complex unwinds double stranded DNA and begins scanning for a sequence complementary to the spacer region of the sgRNA. When a complementary sequence is found, and if there is an appropriate protospacer adjacent motif (PAM; for S. pyogenes a genomic “NGG” found immediately 3′ of the targeted sequence), the nuclease domains of Cas9 cleave both strands of the DNA [57], [59]. The introduction of this DSB must then be repaired to avoid host cell death (Fig. 2). Repair of the DSB by NHEJ commonly results in indel mutations and gene inactivation. Providing a homology repair template induces repair of the break by HR and allows for a desired sequence to be inserted at the cut site.

Fig. 2

CRISPR-Cas9-mediated genome editing. The Cas9-sgRNA complex scans DNA until finding a complementary sequence. Upon binding, the endonuclease domains cleave both DNA strands 3 bases upstream of the PAM sequence. The double strand break is then repaired either by homologous recombination (HR) if an appropriate homology donor is present, or by nonhomologous end-joining (NHEJ). Repair via HR allows for precise genome editing at the target site, while NHEJ introduces short insertions or deletions.

To date, CRISPR-Cas9 systems have been developed to allow gene disruptions and/or markerless integrations in all 6 of the non-conventional yeasts discussed in this review (Table 2). While most systems use a similar strategy for Cas9 expression and nuclear localization (commonly an SV40 C-terminal tag), a variety of strategies for sgRNA expression have been developed. In S. cerevisiae, the native SNR52 RNA polymerase III promoter is often used, as it allows for proper 5′ and 3′ maturation of the expressed sgRNA [57]. A similar sgRNA strategy was used in K. lactis and the resulting CRISPR-Cas9 system was demonstrated by simultaneously introducing three DSBs for multiplexed HR-mediated gene integration, successfully engineering a six gene pathway in a single transformation [35]. A native SNR52 promoter was also used to enable functional CRISPR-Cas9 genome editing in S. stipitis, where gene disruption rates upwards of 80% were achieved [27]. Two different CRISPR-Cas9 systems have been used in Y. lipolytica: the first relies on synthetic RNA polymerase III promoters for sgRNA expression, while the second used an RNA polymerase II promoter with ribozymes flanking the sgRNA to ensure proper 5′ and 3′ maturation [60], [61]. Both systems have been shown to achieve efficient gene disruption and gene integration rates. An analogous synthetic RNA polymerase III strategy was recently used for sgRNA expression to adapt the CRISPR-Cas9 system for use in K. marxianus, where gene disruption rates of 66% have been reported [62]. Successful adaptation of CRISPR-Cas9 to P. pastoris required the use of an RNA polymerase II promoter and ribozymes flanking the sgRNA, achieving efficiencies up to 100% for disruptions [63]. In H. polymorpha, a CRISPR-Cas9 system was developed by using tRNALeu as a promoter to drive sgRNA expression [64]. This system uses the endogenous tRNA processing system for proper sgRNA maturation and disruption efficiencies of up to 71% were achieved.

Table 2

CRISPR-Cas9 systems for genome editing in non-conventional yeasts.

Yeast	Cas9 expression	sgRNA expression	Gene disruption rate	HR rate	Reference
K. lactis	ScFBA1 promoterGenome integrated	SNR52 promoter	N/A	2% (3 integrations simultaneously) in NHEJ deficient strain	[35]
K. marxianus	ScTEF1 promotercodon-optimized	RPR1′-tRNAGly	66%	N/A	[62]
S. stipitis	eno1 promotercodon-optimized	SNR52 promoter	80%	N/A	[27]
Y. lipolytica	TEFintron promotercodon-optimized	TEFintron promoter, flanked by hammerhead and hepatitis delta virus ribozymes	85%	11% in wildtypeup to 100% in NHEJ deficient strain	[60]
Y. lipolytica	UAS1B8-TEF promotercodon-optimized	SCR1′-tRNAGly promoter	92%	64% in wildtypeup to 100% in NHEJ deficient strain	[61]
H. polymorpha	DH3 promoterhuman codon-optimized	tRNALeu	71%	47% (marker integration with selection)	[64]
P. pastoris	HTX1 promoterhuman codon-optimized	HTX1 promoter, flanked by hammerhead and hepatitis delta virus	100%	20%	[63]

To further extend the yeast CRISPR-Cas9 toolbox, Cas9 can be mutated to deactivate its endonuclease activity while retaining its DNA targeting and binding capacity (dCas9). Targeting dCas9 to the promoter region of a gene can sterically block the RNA polymerase machinery from assembling, thus suppressing transcription; a technology referred to as CRISPR interference (CRISPRi) [65]. Fusion of a transcriptional repressor to dCas9 can result in a more effective CRISPRi system. In yeasts, the Mxi1 protein domain has proven most effective to date [66], [67]. In the context of non-conventional yeasts, CRISPRi has so far only been demonstrated in Y. lipolytica [68]. In this case, the synthetic RNA polymerase III system of sgRNA expression and Mxi1 fusion to dCas9 reduced target gene expression to as low as 10% of native expression levels. Finally, the fusion of a transcriptional activator to Cas9 has enabled CRISPR activation (CRISPRa), where native genes can be overexpressed by targeting CRISPRa to a gene's promoter [69]. To date, however, CRISPRa has not been demonstrated in the yeasts discussed in this review. Targeted transcriptional control represents a novel experimental ability in non-conventional yeasts, where well-characterized promoters and tightly tunable inducible promoters are less common relative to model organisms.

Bioprocessing and metabolic engineering with non-conventional yeasts

Despite the challenges of engineering non-conventional yeasts in comparison to the model host S. cerevisiae, a variety of successful bioprocesses have been developed. Here we present selected metabolic engineering examples that exploit desirable phenotypes expressed by K. lactis, K. marxianus, S. stipitis, Y. lipolytica, H. polymorpha, and P. pastoris and discuss the genetic engineering tools used to create new strains of these yeasts. Exemplative products produced from these hosts are presented in Table 3.

Table 3

Expemplative list of non-conventional yeast products.

Yeast	Products	Reference
K. lactis	Proteins
	Native β-galactosidase
	Chymosin
	Brazzein	Reviewed in Ref. [4]
	Human serum albumin (HSA)
	Human interleukin 1-β
	Interferon-α f
	Chemicals
	Glycolic acid	Reviewed in Ref. [3]
	Lactic acid
K. marxianus	Proteins
	Native inulinase
	Native β-galactosidases	Reviewed in Ref. [24]
	Native pectinases
	Chemicals
	Ethanol from dairy waste or lignocellulosic feeds	Reviewed in Ref. [5]
	2-Phenylethanol/2-phenyl ethyl acetate	[70]
	Ethyl acetate	[7]
Y. lipolytica	Proteins
	Lipases
	Proteases
	α-amylases	Reviewed in Ref. [71]
	β-mannases
	Chemicals
	Lipids	Reviewed in Refs. [12] and [3]
	α-Ketoglutaric acid (KGA)	Reviewed in Ref. [71]
	Lycopene	[36]
	Omega-3 eicosapentaenoic acid (EPA)	[72]
	Citric acid	Reviewed in Ref. [3]
S. stipitis	Chemicals
	Ethanol from lignocellulosic feeds	Reviewed in Ref. [21]
	Fumaric acid	[73]
	Lactic acid	[74]
	Xylitol	[75]
H. polymorpha	Proteins
	Hepatitis B surface antigen (HBsAg)
	Insulin
	IFNα-2a	Reviewed in Ref. [76]
	Hexose oxidase
	Phytase
	Chemicals
	Ethanol from various carbon sources	Reviewed in Ref. [17]
P. pastoris	Proteins
	Ecallantide
	Ocriplasmin
	Phytase	Reviewed in Refs. [23] and [77]
	Trypsin
	Phospholipase C
	Chemicals
	(+)-nootkatone	[78]
	violacein	[79]
	β-carotene	[79]

Kluyveromyces lactis

Over the past three decades, considerable efforts have been put towards developing K. lactis as a yeast host for heterologous protein expression. To date, over 100 proteins have been produced, with more than 20% of these demonstrations occurring in the past five years [4]. Examples, such as β-galactosidase and the endopeptidase chymosin, sold by DSM under the trade names of Maxilact and Maxiren (DSM), respectively, have been produced at industrial-scale [4], [80]. The economic success of these processes is, in part, due to the ability of K. lactis to secrete high titers of protein and the ability metabolize inexpensive carbon sources such as waste whey streams produced in the dairy industry.

Strain development for K. lactis bioprocesses is most often achieved through an established and commercially available gene integration technology, pKLac2. The plasmid contains an acetamidase selection marker that allows for growth on acetamide as sole nitrogen source and facilitates multiple integrations into the genome of K. lactis. A mutant variant of the strongly inducible Lac4 promoter eliminates recognition of the promoter by E. coli and thus enables cloning of constructs toxic to E. coli. Efficient protein secretion is achieved using a K. lactis α-mating factor secretion domain [81]. One example of the successful use of the pKLac2 system was the production of cardosin B chymosin, a coagulant essential for cheese production, from galactose media [82]. Another example is the sweetener brazzein, which was produced from galactose with protein titers reaching 104 mg L−1 [83].

In comparison to protein synthesis, the use of K. lactis as a host for chemical biosynthesis has been limited. New CRISPR-Cas9 genome editing systems are, however, enabling multiplexed engineering and driving the field forward. For example, a recent work engineered a synthetic muconic acid pathway by simultaneous integrating six heterologous genes into three different K. lactis loci by HR. While triple integration efficiency was low at 2.1%, the desired strain was constructed in a time-efficient manner and produced ∼0.9 g L−1 muconic acid [35].

Kluyveromyces marxianus

One of the reasons that K. marxianus has attracted interest is its high capacity to produce the volatile short chain ester ethyl acetate [6]. Wild type strains of K. marxianus have been shown to produce ethyl acetate at yields of 0.265 g g−1 glucose (51.4% of maximum) and pilot-scale plants with productivity upwards of 2 g L−1 h−1 using waste whey as a feed stock have been demonstrated [7], [8]. In addition to ethyl acetate, K. marxianus is able to produce fusel alcohols and their corresponding acetate esters. This capacity has been harnessed for 2-phenylethanol production from phenylalanine at industrial scale [5], [70]. Biosynthesis of 2-phenylethanol from glucose and the synthesis of phenylethyl acetate from phenylalanine feeds have also been demonstrated [70], [84].

K. marxianus has also been considered as a host for bioethanol production from lignocellulosic biomass hydrolysates and crude waste whey streams [85], [86]. Commercial production plants have been built or are under consideration in the United States, Ireland, and New Zealand, and rely on production from dairy waste streams [5]. Ethanol fermentation has also been engineered using metabolic engineering and cofactor balancing approaches [87], [88]. In one study, ethanol production from xylose was enhanced by 1) overexpressing heterologous xylose reductase (XYL1) and xylitol dehydrogenase (XYL2), and 2) increasing the capacity of the pentose phosphate pathway and flux towards ethanol through the overexpression of native xylulokinase (XYL3), l-ribulose-5-phosphate 4-epimerase (RPE1), ribose-5-phosphate isomerase (RKI1), transketolase (TKL1), transaldolase (TAL1) genes as well as pyruvate decarboxylase (PDC1) and alcohol dehydrogenase (ADH2) [87]. The heterologous XYL1 and XYL2 genes were selected due to their preference of NADP(H) over NAD(H), thus helping to rectify an imbalance in co-factors when grown on xylose. Further improvement of fermentation efficiencies was achieved by eliminating glycerol production through the disruption of glycerol-3-phosphate dehydrogenase (GPD1). The resulting strain contained disruptions to three native genes and overexpression of two heterologous and seven native genes, and was able to produce ethanol from xylose at rates of 2.49 g L−1 h−1. In this case, strain engineering was achieved by markered gene disruption via HR and sequential random integration facilitated by a URA3 marker. Prior to each gene integration the marker was inactivated by HR with a truncated URA3 cassette and selection on 5-FOA containing media [87], [89].

K. marxianus' high capacity for NHEJ can, for many applications, limit genome editing. However, some researchers have exploited this capacity for multiplexed gene integration. For example, a five-gene pathway for the production of hexanoic acid was integrated in a single transformation by selection on uracil dropout media [90]. In this case, each integrated gene was accompanied by a URA3 selectable marker, resulting in a 50% success rate for full pathway integration. Random integration still proved to be problematic as hexanoic acid production varied widely between successful transformants, likely due to gene integration at critical genomic loci.

Scheffersomyces stipitis

A primary advantage of S. stipitis over other yeasts is its ability to ferment xylose at high rates [9], [10]. This phenotype has been exploited for ethanol production from biomass-derived and pure xylose streams. S. stipitis has also been engineered for higher ethanol tolerance as well as growth inhibiters present in biomass hydrolysates [91]. Due to a lack of efficient genome editing tools, engineering of S. stipitis has been limited to random mutagenesis through UV radiation, adaptive evolution, protoplast fusion, and genome shuffling [92], [93], [94], [95]. Single gene deletions have also been achieved through genomic integration using a selectable genetic marker. For example, a HR method was used to create a HXK1 deficient strain lacking glucose repression and a XYL2 deficient strain that produces xylitol from xylose [75]. In another example, S. stipitis was engineered to efficiently produce lactic acid through random integration of a heterologous LDH gene, with engineered strains producing up to 58 g L−1 lactate from 100 g L−1 xylose [74].

More complex pathway engineering has also been achieved. In one case, the deletion of two genes coupled with the overexpression of four heterologous genes led to the production of 4.67 g L−1 fumaric acid from 20 g L−1 xylose [73]. The plasmid-based pathway was comprised of a fumaric acid biosynthesis steps from Rhizopus oryzae and a fumaric acid transporter from Schizosaccharomyces pombe. Disruption of reaction steps competing with fumaric acid production, such as fumarase genes FUM1 and FUM2, was achieved via HR with a URA3 selectable marker and marker recovery by Cre-loxP. A critical lesson from this work was the need for codon optimization of the heterologous genes, as S. stipitis has an unusual usage of CTG, which it uses to code for serine instead of leucine, as in other yeasts [42].

Yarrowia lipolytica

The oleaginous nature of Y. lipolytica has made it the focus of considerable efforts to convert a range of carbon sources into neutral lipids and lipid-derived compounds [11], [96], [97]. These efforts have been extensively reviewed elsewhere (see Refs. [12], [13] and references therein). Y. lipolytica has also been used for heterologous protein production, but we focus here on its capacity for lipid biosynthesis [71]. In one recent work, high levels of triacylglycerides were engineered [98]. By engineering the conversion of glycolytic NADH to lipid precursors, specifically NADPH and acetyl-CoA, lipid production was increased by ∼25% to 0.27 g g−1 glucose while reducing oxygen requirements of the strain. These improvements, along with a resulting high rate of lipid production (1.2 g L−1h−1), help to move this process closer to industrial feasibility.

In another example, researchers from DuPont used Y. lipolytica as a host for the biosynthesis of the nutritional supplement omega-3 eicosapentaenoic acid (EPA) [72]. The resulting strain gave rise to two commercial products, Newharvest™ EPA oil, a supplement for human consumption, and Verlasso®, a salmon feed with the high EPA biomass. Random integration of 30 copies of nine homologous and heterogeneous genes along with the disruption of β-oxidation resulted in an industrial production strain capable of producing EPA at 15% of dry cell weight and 57% of the total fatty acid content by weight. The aforementioned project relied on genome editing by random integration, thus necessitating marker recovery at each integration step. The recent adaptation of CRISPR-Cas9 for use in Y. lipolytica has alleviated this challenge by enabling site specific, markerless integration [36].

Hansenula polymorpha

The methylotrophic yeast H. polymorpha (previously Pichia angusta or Ogataea polymorpha) was first studied as model organism for peroxisome function as well as nitrate assimilation [14], [15], [76], [99]. The availability of a strong inducible expression system coupled with effective protein secretion and glycosylation has also made H. polymorpha a successful host for protein production. While S. cerevisiae is able to N-glycosylate proteins, it tends to hyperglycosylate with alpha-1,3-linked mannose residues, which triggers immunogenicity in humans [100]. H. polymorpha's glycosylation machinery does not produce alpha-1,3-linked residues and is less prone to hyperglycosylation [76]. Moreover, significant efforts have been put towards optimization of human-like glycosylation [101]. Industrially produced biopharmaceutical examples include, but are not limited to, insulin under the trade name AgB, IFNα-2a sold as Wosulin, and proteins for hepatitis B vaccine HepaVax Gene [16], [18], [102]. With respect to the methylotrophic nature of H. polymorpha, the compartmentalized methanol assimilation pathway has been exploited for the overexpression of peroxisome-dependent pathways. For example, penicillin production is localized, in part, to the peroxisomes. Growth on methanol promotes peroxisome proliferation, efficient heterologous protein expression, and consequently penicillin production [103].

H. polymorpha is also a good candidate for chemical biosynthesis. Thermotolerance, broad substrate utilization, and resistance to a variety of growth inhibitors match well with lignocellulosic as well as crude substrate streams [17]. Ethanol biosynthesis has been engineered with glycerol, cellulose hydrolysate, and starch-derived sugars as process inputs [104], [105], [106], [107], [108]. Most commonly, pathway engineering has been achieved by random integration or integration into the telomeric regions of the H. polymorpha genome by HR. While H. polymorpha easily accepts integration of heterologous genes, high NHEJ capacity makes it hard to disrupt genes. In a recent study, disruption of a CAT8, a transcriptional activator that is involved in gluconeogenesis, respiration, the glyoxylic cycle and ethanol catabolism, increased ethanol yields to 12.5 g/L at 45 °C. This work produced disruption efficiencies of 2.5% and below using a homology donor with a resistance marker [109]. The recent development of a CRISPR-Cas9 in H. polymorpha has enabled gene disruption rates of up to 71%, significantly facilitating future metabolic engineering approaches [64].

Pichia pastoris

Similar to H. polymorpha, early interest in P. pastoris was driven by its ability to grow on methanol as sole carbon source, with research and development focusing on the production of single-cell protein [18]. Its use in bioprocessing is also similar to H. polymorpha, as P. pastoris is a common yeast host for protein production for the pharmaceutical, and feed and food industries [18], [77]. Processes benefit from effective protein secretion as well as strong constitutive and inducible promoters engineered from the methanol assimilation pathway [18], [110]. Glycosylation pathways have been extensively engineered, thus facilitating mammalian protein production [111], [112], [113]. Bioprocesses also benefit from P. pastoris' ability to grow to high cell density and efficiently produce membrane proteins [18], [19], [20]. These characteristics have been exploited for the industrial production of several proteins including ecallantide (trade name Kalbitor® produced by Dyax), a recombinant protein inhibitor of the plasma protease kallikrein, and ocriplasmin (trade name Jetrea® produced by ThromboGenics), a truncated recombinant form of human plasmin [22], [23].

Due to low expression from plasmids, heterologous genes are usually integrated into the genome [18]. These traditional techniques have also been used for metabolic pathway engineering. For example, a biosynthetic pathway for the terpenoid (+)-nootkatone was engineered in P. pastoris in a KU70 deficient strain [78]. The pathway required the integration of four heterologous and one homologous overexpression cassettes, which was achieved by targeted integration. Central to the success of this pathway was expression of two membrane-associated cytochrome P450 enzymes. The resulting strain produced upwards of 200 mg L−1 of (+)-nootkatone in a high cell density fermentation. In a different example, P. pastoris was used to construct a nine gene polycistronic pathway using a 2A sequence that causes a ribosomal skip that terminates translation at the final proline codon of its C-terminally located conserved sequence ‘‘NPGP’. This allows for production of multiple proteins from a single mRNA [79]. The system was used to produce the pigments violacein and β-carotene. This study served as a proof-of-concept for stable and balanced multi-enzyme pathway expression using a single promoter, and will facilitate future metabolic engineering approaches in P. pastoris.

Perspectives

Non-conventional yeasts have been extensively used for a range of biotechnological applications. So far, wild type strains and straightforward pathway engineering that leverages advantageous phenotypes native to the host have been the focus. With the increasing availability of next generation sequencing, genome editing tools, and the development of system wide –omics studies, more advanced understanding of the unique metabolisms and physiologies of non-conventional yeast has become attainable. Future engineering efforts will need to leverage these emerging systems and synthetic biology tools to address a critical lack of fundamental biochemical information, maximize the desired phenotypes, and increase productivity to reach industrially relevant production yields of new products.

Non-conventional yeast engineering will also be advanced by the application of genome-wide engineering tools. Tools such as yeast oligo-mediated genome engineering (YOGE, a recombineering strategy) and the yeast deletion collection in S. cerevisiae demonstrate the power that functional genomics studies can have in yeast [116], [117]. While neither YOGE nor a full deletion collection are feasible in each non-conventional yeast of interest, an alternative strategy seems poised to fill this niche. Genome-wide CRISPR-Cas9 loss of function screens will allow researchers to perform analogous functional genomics studies by transforming pooled plasmids to introduce an indel into each gene in the genome separately [118], [119]. Already widely used and validated in mammalian studies, the application of genome-wide CRISPR-Cas9 screens will greatly advance engineering in non-conventional yeasts, and will allow for further enhancement of desirable phenotypes.

While this review mainly focuses on genome and pathway engineering, other methods and techniques, such as genome-scale modeling and metabolic flux balance analysis, have been used to guide strain engineering. For example, such models and analyses were used to optimize lipid production in Y. lipolytica and assess the biotechnological potential of P. pastoris and S. stipitis [114], [115]. Culture condition optimization has also been prominently featured in process development with non-conventional yeast. For example, low iron content media and in situ product removal strategies have led to the high rate production of ethyl acetate and 2-phenylethanol in wild type strains of K. marxianus [7], [70].

Most often, the limits of metabolic engineering and synthetic biology have been pushed using common lab strains of S. cerevisiae and E. coli. At the same time, many industrial biotechnology efforts have relied on wild type strains and traditional mutagenesis methods to create viable bioprocesses from non-conventional yeasts. As new systems and synthetic biology methods and tools are adapted for use in non-conventional yeasts, we expect that new bioprocesses that exploit desired phenotypes in non-conventional yeasts will be developed and that these yeasts will become new model strain on their own merits.