Patent Application
20240124907
This application includes a sequence listing which has been submitted concurrently herewith as the sequence listing ST26 format XML file “ZGMNP011WO.xml”, file size 278,085 bytes, created on Jul. 10, 2023, and is hereby incorporated by reference in its entirety.
The present disclosure relates generally to the area of engineering microbes for production of histamine by fermentation.
Biogenic amines are organic bases endowed with biological activity, which are frequently found in fermented foods and beverages. Histamine is known to exist in nature in fermented foods such as yogurt (13-36 mg/kg) [1], miso (24 mg/kg) [2], and red wine (24 mg/L) [3]. Some bacteria that live in the human gut also make histamine, and it functions to regulate the immune system by an anti-inflammatory effect [4]. Production of histamine in fermented foods relies on a source of proteins that contain histidine and microbes that histidine decarboxylase. Histamine is the decarboxylation product of histidine that is catalyzed specifically by the enzyme histidine decarboxylase (EC 4.1.1.22). Production of histamine in an industrial fermentation from simple, non-protein, carbon and nitrogen sources requires assembly of a pathway with improved biosynthesis of the amino acid precursor histidine and a highly active histidine decarboxylase.
The disclosure provides engineered microbial cells, cultures of the microbial cells, and methods for the production of histamine, including the following:
Embodiment 1: An engineered microbial cell that expresses a non-native histidine decarboxylase, wherein the engineered microbial cell produces histamine.
Embodiment 2: The engineered microbial cell of embodiment 1, wherein the engineered microbial cell includes increased activity of one or more upstream histamine pathway enzyme(s), said increased activity being increased relative to a control cell.
Embodiment 3: The engineered microbial cell of embodiment 2, wherein the one or more upstream histamine pathway enzyme(s) are selected from the group consisting of an ATP phosphoribosyltransferase, a phosphoribosyl-ATP pyrophosphatase, a phosphoribosyl-AMP cyclohydrolase, a 5′ProFAR isomerase, an imidazole-glycerol phosphate synthase, an imidazole-glycerol phosphate dehydratase, a histidinol-phosphate aminotransferase, a histidinol-phosphate phosphatase, histidinol dehydrogenase, and a ribose phosphate pyrophosphokinase.
Embodiment 4: The engineered microbial cell of any one of embodiments 1-3, wherein the engineered microbial cell includes reduced activity of one or more enzyme(s) that consume one or more histamine pathway precursors, said reduced activity being reduced relative to a control cell.
Embodiment 5: The engineered microbial cell of embodiment 4, wherein the one or more enzyme(s) that consume one or more histamine pathway precursors are selected from the group consisting of an enolase, a pyruvate dehydrogenase, a pentose phosphate pathway sugar isomerase, a transaldolase, a transketolase, a ribulose-5-phosphate epimerase, and a ribulose-5-phosphate isomerase.
Embodiment 6: The engineered microbial cell of embodiment 4 or embodiment 5, wherein the reduced activity is achieved by replacing a native promoter of a gene for said one or more enzymes with a less active promoter.
Embodiment 7: The engineered microbial cell of any one of embodiments 1-6, wherein the engineered microbial cell additionally expresses a feedback-deregulated glucose-6-phosphate dehydrogenase or a feedback-deregulated ATP phosphoribosyltransferase.
Embodiment 8: An engineered microbial cell, wherein the engineered microbial cell includes means for expressing a non-native histidine decarboxylase, wherein the engineered microbial cell produces histamine.
Embodiment 9: The engineered microbial cell of embodiment 8, wherein the engineered microbial cell includes means for increasing the activity of one or more upstream histamine pathway enzyme(s), said increased activity being increased relative to a control cell.
Embodiment 10: The engineered microbial cell of embodiment 9, wherein the one or more upstream histamine pathway enzyme(s) are selected from the group consisting of an ATP phosphoribosyltransferase, a phosphoribosyl-ATP pyrophosphatase, a phosphoribosyl-AMP cyclohydrolase, a 5′ProFAR isomerase, an imidazole-glycerol phosphate synthase, an imidazole-glycerol phosphate dehydratase, a histidinol-phosphate aminotransferase, a histidinol-phosphate phosphatase, a histidinol dehydrogenase, and a ribose phosphate pyrophosphokinase.
Embodiment 11: The engineered microbial cell of any one of embodiments 8-10, wherein the engineered microbial cell includes means for reducing the activity of one or more enzyme(s) that consume one or more histamine pathway precursors, said reduced activity being reduced relative to a control cell.
Embodiment 12: The engineered microbial cell of embodiment 11, wherein the one or more enzyme(s) that consume one or more histamine pathway precursors are selected from the group consisting of an enolase, a pyruvate dehydrogenase, pentose phosphate pathway sugar isomerase, a transketolase, a translaldolase, a ribulose-5-phosphate epimerase, and a ribulose-5-phosphate isomerase.
Embodiment 13: The engineered microbial cell of embodiment 11 or embodiment 12, wherein the reduced activity is achieved by means for replacing a native promoter of a gene for said one or more enzymes with a less active promoter.
Embodiment 14: The engineered microbial cell of any one of embodiments 8-13, wherein the engineered microbial cell additionally includes means for expressing glucose-6-phosphate dehydrogenase or a feedback-deregulated ATP phosphoribosyltransferase.
Embodiment 15: The engineered microbial cell of any one of embodiments 1-14, wherein the engineered microbial cell includes a fungal cell.
Embodiment 16: The engineered microbial cell of embodiment 15, wherein the engineered microbial cell includes a yeast cell.
Embodiment 17: The engineered microbial cell of embodiment 16, wherein the yeast cell is a cell of the genus Saccharomyces or Yarrowia.
Embodiment 18: The engineered microbial cell of embodiment 17, wherein the yeast cell is a cell of the genus Saccharomyces and of the species cerevisiae.
Embodiment 19: The engineered microbial cell of embodiment 17, wherein the yeast cell is a cell of the genus Yarrowia and of the species lipolytica.
Embodiment 20: The engineered microbial cell of any one of embodiments 1-19, wherein the non-native histidine decarboxylase includes a histidine decarboxylase having at least 70% amino acid sequence identity with a histidine decarboxylase from Chromobacterium sp. LK1 or from Acinetobacter baumannii strain AB0057.
Embodiment 21: The engineered microbial cell of any one of embodiments 1 and 16-20, wherein the engineered microbial cell includes increased activity of one or more upstream histamine pathway enzyme(s), said increased activity being increased relative to a control cell, wherein the one or more upstream histamine pathway enzyme(s) comprise an ATP phosphoribosyltransferase.
Embodiment 22: The engineered microbial cell of embodiment 21 wherein the increased activity of the ATP phosphoribosyltransferase is achieved by heterologously expressing it.
Embodiment 23: The engineered microbial cell of embodiment 22, wherein the heterologous ATP phosphoribosyltransferase has at least 70% amino acid sequence identity with an ATP phosphoribosyltransferase from S. cerevisiae.
Embodiment 24: The engineered microbial cell of any one of embodiments 16-23, wherein the engineered microbial cell includes a feedback-deregulated variant of a Corynebacterium glutamicum ATP phosphoribosyltransferase.
Embodiment 25: The engineered microbial cell of any one of embodiments 1-14, wherein the engineered microbial cell is a bacterial cell.
Embodiment 26: The engineered microbial cell of embodiment 25, wherein the bacterial cell is a cell of the genus Corynebacteria or Bacillus.
Embodiment 27: The engineered microbial cell of embodiment 26, wherein the bacterial cell is a cell of the genus Corynebacteria and of the species glutamicum.
Embodiment 28: The engineered microbial cell of embodiment 26, wherein the bacterial cell is a cell of the genus Bacillus and of the species subtilis.
Embodiment 29: The engineered microbial cell of any one of embodiments 25-28, wherein the non-native histidine decarboxylase includes a histidine decarboxylase having at least 70% amino acid sequence identity with a histidine decarboxylase from Acinetobacter baumannii or from Lactobacillus sp. (strain 30a).
Embodiment 30: The engineered microbial cell of any one of embodiments 1 and 25-29, wherein the engineered microbial cell includes increased activity of one or more upstream histamine pathway enzyme(s), said increased activity being increased relative to a control cell, wherein the one or more upstream histamine pathway enzyme(s) comprise an ATP phosphoribosyltransferase and an imidazole-glycerol phosphate dehydratase.
Embodiment 31: The engineered microbial cell of embodiment 30, wherein the increased activity of the ATP phosphoribosyltransferase or the imidazole-glycerol phosphate dehydratase is achieved by heterologously expressing it.
Embodiment 32: The engineered microbial cell of embodiment 31, wherein the heterologous ATP phosphoribosyltransferase has at least 70% amino acid sequence identity with an ATP phosphoribosyltransferase from Saccharomyces cerevisiae S288c or from Salmonella typhimurium LT2, or the heterologous imidazole-glycerol phosphate dehydratase has at least 70% amino acid sequence identity with an imidazole-glycerol phosphate dehydratase from Corynebacterium glutamicum.
Embodiment 33: The engineered microbial cell of any one of embodiments 25-32, wherein the engineered microbial cell includes a feedback-deregulated variant of a Salmonella typhimurium ATP phosphoribosyltransferase.
Embodiment 34: The engineered microbial cell of any one of embodiments 1-33, wherein, when cultured, the engineered microbial cell produces histamine at a level of at least 20 mg/L of culture medium.
Embodiment 35: The engineered microbial cell of embodiment 34, wherein, when cultured, the engineered microbial cell produces histamine at a level of at least 300 mg/L of culture medium.
Embodiment 36: A culture of engineered microbial cells according to any one of embodiments 1-35.
Embodiment 37: The culture of embodiment 36, wherein the engineered microbial cells are present in a concentration such that the culture has an optical density at 600 nm of 10-500.
Embodiment 38: The culture of any one of embodiments 36-37, wherein the culture includes histamine.
Embodiment 39: The culture of any one of embodiments 36-38, wherein the culture includes histamine at a level at least 20 mg/L of culture medium.
Embodiment 40: A method of culturing engineered microbial cells according to any one of embodiments 1-35, the method including culturing the cells under conditions suitable for producing histamine.
Embodiment 41: The method of embodiment 40, wherein the method includes fed-batch culture, with an initial glucose level in the range of 1-100 g/L, followed controlled sugar feeding.
Embodiment 42: The method of any one of embodiments 40-41, wherein the fermentation substrate includes glucose and a nitrogen source selected from the group consisting of urea, an ammonium salt, ammonia, and any combination thereof.
Embodiment 43: The method of any one of embodiments 40-42, wherein the culture is pH-controlled during culturing.
Embodiment 44: The method of any one of embodiments 40-43, wherein the culture is aerated during culturing.
Embodiment 45: The method of any one of embodiments 40-44, wherein the engineered microbial cells produce histamine at a level at least 20 mg/L of culture medium.
Embodiment 46: The method of any one of embodiments 40-45, wherein the method additionally includes recovering histamine from the culture.
Embodiment 47: A method for preparing histamine using microbial cells engineered to produce histamine, the method including: (a) expressing a non-native histidine decarboxylase in microbial cells; (b) cultivating the microbial cells in a suitable culture medium under conditions that permit the microbial cells to produce histamine, wherein the histamine is released into the culture medium; and isolating histamine from the culture medium.
This disclosure describes a method for the production of the small molecule histamine via fermentation by a microbial host from simple carbon and nitrogen sources, such as glucose and urea, respectively. This objective can be achieved by introducing a non-native metabolic pathway into a suitable microbial host for industrial fermentation of large-scale chemical products. Illustrative hosts include Saccharomyces cerevisiae, Yarrowia lypolytica, Corynebacteria glutamicum, and Bacillus subtilis. The engineered metabolic pathway links the central metabolism of the host to a non-native pathway to enable the production of histamine. The simplest embodiment of this approach is the expression of an enzyme, a non-native histidine decarboxylase enzyme, in a microbial host strain that can produce histidine. Further engineering of the metabolic pathway by modification of the microbial host central metabolism through overexpression and mutation of a key upstream pathway enzyme, ATP phosphoribosyltransferase, enabled titers of 505 mg/L histamine to be achieved.
The following disclosure describes how to engineer a microbe with the necessary characteristics to produce industrially feasible titers of histamine from simple carbon and nitrogen sources. Active histidine decarboxylases have been identified, and it has been found that feedback-deregulated ATP phosphoribosyltransferase and/or constitutive expression of native ATP phosphoribosyltransferase improve the titers of histidine by fermentation.
Terms used in the claims and specification are defined as set forth below unless otherwise specified.
The term “fermentation” is used herein to refer to a process whereby a microbial cell converts one or more substrate(s) into a desired product (such as histamine) by means of one or more biological conversion steps, without the need for any chemical conversion step.
The term “engineered” is used herein, with reference to a cell, to indicate that the cell contains at least one targeted genetic alteration introduced by man that distinguishes the engineered cell from the naturally occurring cell.
The term “native” is used herein to refer to a cellular component, such as a polynucleotide or polypeptide, that is naturally present in a particular cell. A native polynucleotide or polypeptide is endogenous to the cell.
When used with reference to a polynucleotide or polypeptide, the term “non-native” refers to a polynucleotide or polypeptide that is not naturally present in a particular cell.
When used with reference to the context in which a gene is expressed, the term “non-native” refers to a gene expressed in any context other than the genomic and cellular context in which it is naturally expressed. A gene expressed in a non-native manner may have the same nucleotide sequence as the corresponding gene in a host cell, but may be expressed from a vector or from an integration point in the genome that differs from the locus of the native gene.
The term “heterologous” is used herein to describe a polynucleotide or polypeptide introduced into a host cell. This term encompasses a polynucleotide or polypeptide, respectively, derived from a different organism, species, or strain than that of the host cell. In this case, the heterologous polynucleotide or polypeptide has a sequence that is different from any sequence(s) found in the same host cell. However, the term also encompasses a polynucleotide or polypeptide that has a sequence that is the same as a sequence found in the host cell, wherein the polynucleotide or polypeptide is present in a different context than the native sequence (e.g., a heterologous polynucleotide can be linked to a different promotor and inserted into a different genomic location than that of the native sequence). “Heterologous expression” thus encompasses expression of a sequence that is non-native to the host cell, as well as expression of a sequence that is native to the host cell in a non-native context.
As used with reference to polynucleotides or polypeptides, the term “wild-type” refers to any polynucleotide having a nucleotide sequence, or polypeptide having an amino acid, sequence present in a polynucleotide or polypeptide from a naturally occurring organism, regardless of the source of the molecule; i.e., the term “wild-type” refers to sequence characteristics, regardless of whether the molecule is purified from a natural source; expressed recombinantly, followed by purification; or synthesized. The term “wild-type” is also used to denote naturally occurring cells.
A “control cell” is a cell that is otherwise identical to an engineered cell being tested, including being of the same genus and species as the engineered cell, but lacks the specific genetic modification(s) being tested in the engineered cell.
Enzymes are identified herein by the reactions they catalyze and, unless otherwise indicated, refer to any polypeptide capable of catalyzing the identified reaction. Unless otherwise indicated, enzymes may be derived from any organism and may have a native or mutated amino acid sequence. As is well known, enzymes may have multiple functions and/or multiple names, sometimes depending on the source organism from which they derive. The enzyme names used herein encompass orthologs, including enzymes that may have one or more additional functions or a different name.
The term “feedback-deregulated” is used herein with reference to an enzyme that is normally negatively regulated by a downstream product of the enzymatic pathway (i.e., feedback-inhibition) in a particular cell. In this context, a “feedback-deregulated” enzyme is a form of the enzyme that is less sensitive to feedback-inhibition than the native enzyme native to the cell. A feedback-deregulated enzyme may be produced by introducing one or more mutations into a native enzyme. Alternatively, a feedback-deregulated enzyme may simply be a heterologous, native enzyme that, when introduced into a particular microbial cell, is not as sensitive to feedback-inhibition as the native, native enzyme. In some embodiments, the feedback-deregulated enzyme shows no feedback-inhibition in the microbial cell.
The term “histamine” refers to 2-(1I-Imidazol-4-yl)ethanamine (CAS #51-45-6).
The term “sequence identity,” in the context of two or more amino acid or nucleotide sequences, refers to two or more sequences that are the same or have a specified percentage of amino acid residues or nucleotides that are the same, when compared and aligned for maximum correspondence, as measured using a sequence comparison algorithm or by visual inspection.
For sequence comparison to determine percent nucleotide or amino acid sequence identity, typically one sequence acts as a “reference sequence,” to which a “test” sequence is compared. When using a sequence comparison algorithm, test and reference sequences are input into a computer, subsequence coordinates are designated, if necessary, and sequence algorithm program parameters are designated. The sequence comparison algorithm then calculates the percent sequence identity for the test sequence relative to the reference sequence, based on the designated program parameters. Alignment of sequences for comparison can be conducted using BLAST set to default parameters.
The term “titer,” as used herein, refers to the mass of a product (e.g., histamine) produced by a culture of microbial cells divided by the culture volume.
As used herein with respect to recovering histamine from a cell culture, “recovering” refers to separating the histamine from at least one other component of the cell culture medium.
Histamine Biosynthesis Pathway
Histamine is typically derived from the amino acid histidine. The histamine biosynthesis pathway is shown in
Engineering for Microbial Histamine Production
Any histidine decarboxylase that is active in the microbial cell being engineered may be introduced into the cell, typically by introducing and expressing the gene(s) encoding the enzyme(s)s using standard genetic engineering techniques. Suitable histidine decarboxylase may be derived from any source, including plant, archaeal, fungal, gram-positive bacterial, and gram-negative bacterial sources. Exemplary sources include, but are not limited to: Aeromonas salmonicida subsp. pectinolytica 34mel, Acinetobacter baumannii (strain AB0057), Chromobacterium haemolyticum, Chromobacterium sp. LK1, Citrobacter pasteurii, Drosophila melanogaster, Lactobacillus aviarius DSM 20655, Lactobacillus fructivorans, Lactobacillus reuteri, Lactobacillus sp. (strain 30a), Methanosarcina barkeri (strain Fusaro/DSM804), Methanosarcina barkeri str. Wiesmoor, Morganella psychrotolerans, Mus musculus, Oenococcus oeni (Leuconostoc oenos), Pseudomonas putida (Arthrobacter siderocapsulatus), Pseudomonas rhizosphaerae, Pseudomonas sp. bs2935, Solanum lycopersicum, Oryza sativa, Penicillium marneffei, Streptomyces hygroscopicus, Pseudomonas putida, Arabidopsis thaliana (Mouse-ear cress), Glycine soja (Wild soybean), Solanum lycopersicum (Tomato) (Lycopersicon esculentum), Clostridium perfringens, Lactobacillus buchneri, Drosophila melanogaster (Fruitfly), Morganella morganii (Proteus morganii), E. coli, Bos taurus (Bovine), Raoutella planticol (Klebsiella planticola), Acinetobacter baumannii, Acinetobacter haemolyticus, Photobacterium damselae, Tetragenococcus muriaticus, Moritella sp JT01, Streptococcus thermophilus, Enterobacter aerogenes, Citrobacter youngae, Raoultella omithinolytica, and Raoultella planticola.
One or more copies of histidine decarboxylase gene can be introduced into a selected microbial host cell. If more than one copy of a gene is introduced, the copies can have the same or different nucleotide sequences. In some embodiments, one or both of the heterologous gene(s) is/are expressed from a strong, constitutive promoter. In some embodiments, the heterologous histidine decarboxylase gene(s) is/are expressed from an inducible promoter. The heterologous gene(s) can optionally be codon-optimized to enhance expression in the selected microbial host cell. Illustrative codon-optimization tables for hosts used in the Examples are as follows: Bacillus subtilis Kazusa codon table: www.kazusa.or.jp/codon/cgi-bin/showcodon.cgi?species=1423&aa=1&style=N; Yarrowia lipolytica Kazusa codon table: www.kazusa.or.jp/codon/cgi-bin/showcodon.cgi?species=4952&aa=1&style=N; Corynebacteria glutamicum Kazusa codon table: www.kazusa.or.jp/codon/cgi-bin/showcodon.cgi?species=340322&aa=1&style=N; Saccharomyces cerevisiae Kazusa codon table: http://www.kazusa.or.jp/codon/cgi-bin/showcodon.cgi?species=4932&aa=1&style=N. Also used, was a modified, combined codon usage scheme for S. cerevisae and C. glutamicum, which is reproduced below.
Increasing the Activity of Upstream Enzymes
One approach to increasing histamine production in a microbial cell that is capable of such production is to increase the activity of one or more upstream enzymes in the histamine biosynthesis pathway. Upstream pathway enzymes include all enzymes involved in the conversions from a feedstock all the way to into the last native metabolite (histidine, in the illustrative microbial cells described in the Examples below). Such enzymes include an ATP phosphoribosyltransferase, a phosphoribosyl-ATP pyrophosphatase, a phosphoribosyl-AMP cyclohydrolase, a 5′ProFAR isomerase, an imidazole-glycerol phosphate synthase, an imidazole-glycerol phosphate dehydratase, a histidinol-phosphate aminotransferase, a histidinol-phosphate phosphatase, histidinol dehydrogenase, and a ribose phosphate pyrophosphokinase. Suitable upstream pathway genes encoding these enzymes may be derived from any source, including, for example, those discussed above as sources for a histidine decarboxylase gene.
In some embodiments, the activity of one or more upstream pathway enzymes is increased by modulating the expression or activity of the native enzyme(s). For example, native regulators of the expression or activity of such enzymes can be exploited to increase the activity of suitable enzymes.
Alternatively, or in addition, one or more promoters can be substituted for native promoters using, for example, a technique such as that illustrated in
In some embodiments, the activity of one or more upstream pathway enzymes is supplemented by introducing one or more of the corresponding genes into the histidine decarboxylase-expressing microbial host cell. An introduced upstream pathway gene may be from an organism other than that of the host cell or may simply be an additional copy of a native gene. In some embodiments, one or more such genes are introduced into a microbial host cell capable of histamine production and expressed from a strong constitutive promoter and/or can optionally be codon-optimized to enhance expression in the selected microbial host cell.
Example 1 describes the successful engineering of C. glutamicum to express a heterologous histamine decarboxylase from Acinetobacter baumannii (SEQ ID NO:1) and to constitutively express a heterologous C. glutamicum imidazoleglycerol-phosphate dehydratase (SEQ ID NO:2). This strain resulted from two rounds of genetic engineering and produced histamine at a titer of 24 mg/L of culture medium. This titer was increased to 68 mg/L in a C. glutamicum strain engineered to express a histamine decarboxylase from Acinetobacter baumannii (strain AB0057) (SEQ ID NO:1) and an ATP phosphoribosyltransferase from S. cerevisiae S288c (SEQ ID NO: 3).
Example 2 describes the successful engineering of Y. lypolytica to express a histidine decarboxylase from Acinetobacter baumannii (strain AB0057) (SEQ ID NO: 1) and an ATP phosphoribosyltransferase from S. cerevisiae S288c (SEQ ID NO:3) to give a histamine titer of 505 mg/L. Example 2 also describes the engineering B. subtilis to express a histamine decarboxylase from Lactobacillus sp. (strain 30a) (SEQ ID NO:4) and an ATP phosphoribosyltransferase from Salmonella typhimurium LT2 (SEQ ID NO:5) to give a histamine titer of 18 mg/L. Also in Example 2, S. cerevisiae was engineered to express a histamine decarboxylase from Chromobacterium sp. LK1 (SEQ ID NO:6) and an ATP phosphoribosyltransferase S. cerevisiae S288c (SEQ ID NO: 3) to give a histamine titer of 111 mg/L.
In various embodiments, the engineering of a histamine-producing microbial cell to increase the activity of one or more upstream pathway enzymes increases the histamine titer by at least 10, 20, 30, 40, 50, 60, 70, 80, or 90 percent or by at least 2-fold, 2.5-fold, 3-fold, 3.5-fold, 4-fold, 4.5-fold, 5-fold, 5.5-fold, 6-fold, 6.5-fold, 7-fold, 7.5-fold, 8-fold, 8.5-fold, 9-fold, 9.5-fold, 10-fold, 11-fold, 12-fold, 13-fold, 14-fold, 15-fold, 16-fold, 17-fold, 18-fold, 19-fold, 20-fold, 21-fold, 22-fold, 23-fold, 24-fold, 25-fold, 30-fold, 35-fold, 40-fold, 45-fold, 50-fold, 55-fold, 60-fold, 65-fold, 70-fold, 75-fold, 80-fold, 85-fold, 90-fold, 95-fold, or 100-fold. In various embodiments, the increase in histamine titer is in the range of 10 percent to 100-fold, 2-fold to 50-fold, 5-fold to 40-fold, 10-fold to 30-fold, or any range bounded by any of the values listed above. (Ranges herein include their endpoints.) These increases are determined relative to the histamine titer observed in a histamine-producing microbial cell that lacks any increase in activity of upstream pathway enzymes. This reference cell may have one or more other genetic alterations aimed at increasing histamine production, e.g., the cell may express a feedback-deregulated enzyme.
In various embodiments, the histamine titers achieved by increasing the activity of one or more upstream pathway genes are at least 1, 10, 20, 30, 40, 50, 75, 100, 200, 300, 400, 500, 600, 700, 800, or 900 mg/L or at least 1, 1.5, 2, 2.5, 3, 3.5, 4, 4.5, 5, or 10 gm/L. In various embodiments, the titer is in the range of 10 mg/L to 10 gm/L, 20 mg/L to 5 gm/L, 50 mg/L to 4 gm/L, 100 mg/L to 3 gm/L, 500 mg/L to 2 gm/L or any range bounded by any of the values listed above.
Since histidine biosynthesis is subject to feedback inhibition, another approach to increasing histamine production in a microbial cell engineered to produce histamine is to introduce feedback-deregulated forms of one or more enzymes that are normally subject to feedback regulation. Examples of such enzymes include glucose-6-phosphate dehydrogenase and ATP phosphoribosyltransferase. A feedback-deregulated form can be a heterologous, native enzyme that is less sensitive to feedback inhibition than the native enzyme in the particular microbial host cell. Alternatively, a feedback-deregulated form can be a variant of a native or heterologous enzyme that has one or more mutations or truncations rendering it less sensitive to feedback inhibition than the corresponding native enzyme. Examples of the latter include a variant ATP phosphoribosyltransferase (from C. glutamicum) containing the amino acid substitutions N215K, L231F, and T235A (SEQ ID NO:7) and a variant ATP phosphoribosyltransferase (from Salmonella typhimurium) containing the deletion of amino acids Q207 and E208 (SEQ ID NO:5).
In various embodiments, the engineering of a histamine-producing microbial cell to express a feedback-deregulated enzymes increases the histamine titer by at least 10, 20, 30, 40, 50, 60, 70, 80, or 90 percent or by at least 2-fold, 2.5-fold, 3-fold, 3.5-fold, 4-fold, 4.5-fold, 5-fold, 5.5-fold, 6-fold, 6.5-fold, 7-fold, 7.5-fold, 8-fold, 8.5-fold, 9-fold, 9.5-fold, 10-fold, 11-fold, 12-fold, 13-fold, 14-fold, 15-fold, 16-fold, 17-fold, 18-fold, 19-fold, 20-fold, 21-fold, 22-fold, 23-fold, 24-fold, 25-fold, 30-fold, 35-fold, 40-fold, 45-fold, 50-fold, 55-fold, 60-fold, 65-fold, 70-fold, 75-fold, 80-fold, 85-fold, 90-fold, 95-fold, or 100-fold. In various embodiments, the increase in histamine titer is in the range of 10 percent to 100-fold, 2-fold to 50-fold, 5-fold to 40-fold, 10-fold to 30-fold, or any range bounded by any of the values listed above. These increases are determined relative to the histamine titer observed in a histamine-producing microbial cell that does not express a feedback-deregulated enzyme. This reference cell may (but need not) have other genetic alterations aimed at increasing histamine production, i.e., the cell may have increased activity of an upstream pathway enzyme resulting from some means other than feedback-insensitivity.
In various embodiments, the histamine titers achieved by using a feedback-deregulated enzyme to increase flux though the histamine biosynthetic pathway are at least 100, 200, 300, 400, 500, 600, 700, 800, or 900 μg/L, or at least 1, 10, 50, 75, 100, 200, 300, 400, 500, 600, 700, 800, or 900 mg/L or at least 1, 1.5, 2, 2.5, 3, 3.5, 4, 4.5, 5, 10, 20, 50 g/L. In various embodiments, the titer is in the range of 50 μg/L to 50 g/L, 75 μg/L to 20 g/L, 100 μg/L to 10 g/L, 200 μg/L to 5 g/L, 500 μg/L to 4 g/L, 1 mg/L to 3 g/L, 500 mg/L to 2 g/L or any range bounded by any of the values listed above.
The approaches of supplementing the activity of one or more native enzymes and/or introducing one or more feedback-deregulated enzymes can be combined in histamine decarboxylase-expressing microbial cells to achieve even higher histamine production levels. For example, a histamine titer of 385 mg/L was achieved in S. cerevisiae in two rounds of engineering from the introduction of three genes: a histidine decarboxylase gene (from Chromobacterium sp. LK1) (SEQ ID NO:6), an ATP phosphoribosyltransferase (from C. glutamicum) containing the amino acid substitutions N215K, L231F, and T235A (SEQ ID NO:7), and a constitutively expressed ATP phosphoribosyltransferase from S. cerevisiae S288c (SEQ ID NO:3). (Example 1.)
Another approach to increasing histamine production in a microbial cell that is capable of such production is to decrease the activity of one or more enzymes that consume one or more histamine pathway precursors. In some embodiments, the activity of one or more such enzymes is reduced by modulating the expression or activity of the native enzyme(s). Illustrative enzymes of this type include an enolase, a pyruvate dehydrogenase, a pentose phosphate pathway sugar isomerase, a transaldolase, a transketolase, a ribulose-5-phosphate epimerase, and a aribulose-5-phosphate isomerase. The activity of such enzymes can be decreased, for example, by substituting the native promoter of the corresponding gene(s) with a less active or inactive promoter or by deleting the corresponding gene(s). See
In various embodiments, the engineering of a histamine-producing microbial cell to reduce precursor consumption by one or more side pathways increases the histamine titer by at least 10, 20, 30, 40, 50, 60, 70, 80, or 90 percent or by at least 2-fold, 2.5-fold, 3-fold, 3.5-fold, 4-fold, 4.5-fold, 5-fold, 5.5-fold, 6-fold, 6.5-fold, 7-fold, 7.5-fold, 8-fold, 8.5-fold, 9-fold, 9.5-fold, 10-fold, 11-fold, 12-fold, 13-fold, 14-fold, 15-fold, 16-fold, 17-fold, 18-fold, 19-fold, 20-fold, 21-fold, 22-fold, 23-fold, 24-fold, 25-fold, 30-fold, 35-fold, 40-fold, 45-fold, 50-fold, 55-fold, 60-fold, 65-fold, 70-fold, 75-fold, 80-fold, 85-fold, 90-fold, 95-fold, or 100-fold. In various embodiments, the increase in histamine titer is in the range of 10 percent to 100-fold, 2-fold to 50-fold, 5-fold to 40-fold, 10-fold to 30-fold, or any range bounded by any of the values listed above. These increases are determined relative to the histamine titer observed in a histamine-producing microbial cell that does not include genetic alterations to reduce precursor consumption. This reference cell may (but need not) have other genetic alterations aimed at increasing histamine production, i.e., the cell may have increased activity of an upstream pathway enzyme.
In various embodiments, the histamine titers achieved by reducing precursor consumption by one or more side pathways are at least 100, 200, 300, 400, 500, 600, 700, 800, or 900 μg/L, or at least 1, 10, 50, 75, 100, 200, 300, 400, 500, 600, 700, 800, or 900 mg/L or at least 1, 1.5, 2, 2.5, 3, 3.5, 4, 4.5, 5, 10, 20, 50 g/L. In various embodiments, the titer is in the range of 50 μg/L to 50 g/L, 75 μg/L to 20 g/L, 100 μg/L to 10 g/L, 200 μg/L to 5 g/L, 500 μg/L to 4 g/L, 1 mg/L to 3 g/L, 500 mg/L to 2 g/L or any range bounded by any of the values listed above.
The approaches of increasing the activity of one or more native enzymes and/or introducing one or more feedback-deregulated enzymes and/or reducing precursor consumption by one or more side pathways can be combined to achieve even higher histamine production levels.
Microbial Host Cells
Any microbe that can be used to express introduced genes can be engineered for fermentative production of histamine as described above. In certain embodiments, the microbe is one that is naturally incapable of fermentative production of histamine. In some embodiments, the microbe is one that is readily cultured, such as, for example, a microbe known to be useful as a host cell in fermentative production of compounds of interest. Bacteria cells, including gram positive or gram negative bacteria can be engineered as described above. Examples include, in addition to C. glutamicum cells, Bacillus subtilus, B. licheniformis, B. lentus, B. brevis, B. stearothermophilus, B. alkalophilus, B. amyloliquefaciens, B. clausii, B. halodurans, B. megaterium, B. coagulans, B. circulans, B. lautus, B. thuringiensis, S. albus, S. lividans, S. coelicolor, S. griseus, Pseudomonas sp., P. alcaligenes, P. citrea, Lactobacilis spp. (such as L. lactis, L. plantarum), L. grayi, E. coli, E. faecium, E. gallinarum, E. casseliflavus, and or E. faecalis cells.
There are numerous types of anaerobic cells that can be used as microbial host cells in the methods described herein. In some embodiments, the microbial cells are obligate anaerobic cells. Obligate anaerobes typically do not grow well, if at all, in conditions where oxygen is present. It is to be understood that a small amount of oxygen may be present, that is, there is some level of tolerance level that obligate anaerobes have for a low level of oxygen. Obligate anaerobes engineered as described above can be grown under substantially oxygen-free conditions, wherein the amount of oxygen present is not harmful to the growth, maintenance, and/or fermentation of the anaerobes.
Alternatively, the microbial host cells used in the methods described herein can be facultative anaerobic cells. Facultative anaerobes can generate cellular ATP by aerobic respiration (e.g., utilization of the TCA cycle) if oxygen is present. However, facultative anaerobes can also grow in the absence of oxygen. Facultative anaerobes engineered as described above can be grown under substantially oxygen-free conditions, wherein the amount of oxygen present is not harmful to the growth, maintenance, and/or fermentation of the anaerobes, or can be alternatively grown in the presence of greater amounts of oxygen.
In some embodiments, the microbial host cells used in the methods described herein are filamentous fungal cells. (See, e.g., Berka & Barnett, Biotechnology Advances, (1989), 7(2):127-154). Examples include Trichoderma longibrachiatum, T. viride, T. koningii, T. harzianum, Penicillum sp., Humicola insolens, H. lanuginose, H. grisea, Chrysosporium sp., C. lucknowense, Gliocladium sp., Aspergillus sp. (such as A. oryzae, A. niger, A. sojae, A. japonicus, A. nidulans, or A. awamori), Fusarium sp. (such as F. roseum, F. graminum F. cerealis, F. oxysporuim, or F. venenatum), Neurospora sp. (such as N. crassa or Hypocrea sp.), Mucor sp. (such as M. miehei), Rhizopus sp., and Emericella sp. cells. In particular embodiments, the fungal cell engineered as described above is A. nidulans, A. awamori, A. oryzae, A. aculeatus, A. niger, A. japonicus, T. reesei, T. viride, F. oxysporum, or F. solani. Illustrative plasmids or plasmid components for use with such hosts include those described in U.S. Patent Pub. No. 2011/0045563.
Yeasts can also be used as the microbial host cell in the methods described herein. Examples include: Saccharomyces sp., Schizosaccharomyces sp., Pichia sp., Hansenula polymorpha, Pichia stipites, Kluyveromyces marxianus, Kluyveromyces spp., Yarrowia lipolytica and Candida sp. In some embodiments, the Saccharomyces sp. is S. cerevisiae (See, e.g., Romanos et al., Yeast, (1992), 8(6):423-488). Illustrative plasmids or plasmid components for use with such hosts include those described in U.S. Pat. No. 7,659,097 and U.S. Patent Pub. No. 2011/0045563.
In some embodiments, the host cell can be an algal cell derived, e.g., from a green algae, red algae, a glaucophyte, a chlorarachniophyte, a euglenid, a chromista, or a dinoflagellate. (See, e.g., Saunders & Warmbrodt, “Gene Expression in Algae and Fungi, Including Yeast,” (1993), National Agricultural Library, Beltsville, Md.). Illustrative plasmids or plasmid components for use in algal cells include those described in U.S. Patent Pub. No. 2011/0045563.
In other embodiments, the host cell is a cyanobacterium, such as cyanobacterium classified into any of the following groups based on morphology: Chlorococcales, Pleurocapsales, Oscillatoriales, Nostocales, Synechosystic or Stigonematales (See, e.g., Lindberg et al., Metab. Eng., (2010) 12(1):70-79). Illustrative plasmids or plasmid components for use in cyanobacterial cells include those described in U.S. Patent Pub. Nos. 2010/0297749 and 2009/0282545 and in Intl. Pat. Pub. No. WO 2011/034863.
Genetic Engineering Methods
Microbial cells can be engineered for fermentative histamine production using conventional techniques of molecular biology (including recombinant techniques), microbiology, cell biology, and biochemistry, which are within the skill of the art. Such techniques are explained fully in the literature, see e.g., “Molecular Cloning: A Laboratory Manual,” fourth edition (Sambrook et al., 2012); “Oligonucleotide Synthesis” (M. J. Gait, ed., 1984); “Culture of Animal Cells: A Manual of Basic Technique and Specialized Applications” (R. I. Freshney, ed., 6th Edition, 2010); “Methods in Enzymology” (Academic Press, Inc.); “Current Protocols in Molecular Biology” (F. M. Ausubel et al., eds., 1987, and periodic updates); “PCR: The Polymerase Chain Reaction,” (Mullis et al., eds., 1994); Singleton et al., Dictionary of Microbiology and Molecular Biology 2nd ed., J. Wiley & Sons (New York, N.Y. 1994).
Vectors are polynucleotide vehicles used to introduce genetic material into a cell. Vectors useful in the methods described herein can be linear or circular. Vectors can integrate into a target genome of a host cell or replicate independently in a host cell. For many applications, integrating vectors that produced stable transformants are preferred. Vectors can include, for example, an origin of replication, a multiple cloning site (MCS), and/or a selectable marker. An expression vector typically includes an expression cassette containing regulatory elements that facilitate expression of a polynucleotide sequence (often a coding sequence) in a particular host cell. Vectors include, but are not limited to, integrating vectors, prokaryotic plasmids, episomes, viral vectors, cosmids, and artificial chromosomes.
Illustrative regulatory elements that may be used in expression cassettes include promoters, enhancers, internal ribosomal entry sites (IRES), and other expression control elements (e.g., transcription termination signals, such as polyadenylation signals and poly-U sequences). Such regulatory elements are described, for example, in Goeddel, Gene Expression Technology: Methods In Enzymology 185, Academic Press, San Diego, Calif. (1990).
In some embodiments, vectors may be used to introduce systems that can carry out genome editing, such as CRISPR systems. See U.S. Patent Pub. No. 2014/0068797, published 6 Mar. 2014; see also Jinek M., et al., “A programmable dual-RNA-guided DNA endonuclease in adaptive bacterial immunity,” Science 337:816-21, 2012). In Type II CRISPR-Cas9 systems, Cas9 is a site-directed endonuclease, namely an enzyme that is, or can be, directed to cleave a polynucleotide at a particular target sequence using two distinct endonuclease domains (HNH and RuvC/RNase H-like domains). Cas9 can be engineered to cleave DNA at any desired site because Cas9 is directed to its cleavage site by RNA. Cas9 is therefore also described as an “RNA-guided nuclease.” More specifically, Cas9 becomes associated with one or more RNA molecules, which guide Cas9 to a specific polynucleotide target based on hybridization of at least a portion of the RNA molecule(s) to a specific sequence in the target polynucleotide. Ran, F. A., et al., (“In vivo genome editing using Staphylococcus aureus Cas9,” Nature 520(7546):186-91, 2015, April 9], including all extended data) present the crRNA/tracrRNA sequences and secondary structures of eight Type II CRISPR-Cas9 systems. Cas9-like synthetic proteins are also known in the art (see U.S. Published Patent Application No. 2014-0315985, published 23 Oct. 2014).
Example 1 describes illustrative integration approaches for introducing polynucleotides and other genetic alterations into the genomes of C. glutamicum and S. cerevisiae cells.
Vectors or other polynucleotides can be introduced into microbial cells by any of a variety of standard methods, such as transformation, conjugation, electroporation, nuclear microinjection, transduction, transfection (e.g., lipofection mediated or DEAE-Dextrin mediated transfection or transfection using a recombinant phage virus), incubation with calcium phosphate DNA precipitate, high velocity bombardment with DNA-coated microprojectiles, and protoplast fusion. Transformants can be selected by any method known in the art. Suitable methods for selecting transformants are described in U.S. Patent Pub. Nos. 2009/0203102, 2010/0048964, and 2010/0003716, and International Publication Nos. WO 2009/076676, WO 2010/003007, and WO 2009/132220.
The above-described methods can be used to produce engineered microbial cells that produce, and in certain embodiments, overproduce, histamine. Engineered microbial cells can have at least 1, 2, 3, 4, 5, 6, 7, 8, 9, 10, 20, 30, 40, 50, 60, 70, 80, 90, 100 or more genetic alterations, such as 30-100 alterations, as compared to a native microbial cell, such as any of the microbial host cells described herein. Engineered microbial cells described in the Example below have one, two, or three genetic alterations, but those of skill in the art can, following the guidance set forth herein, design microbial cells with additional alterations. In some embodiments, the engineered microbial cells have not more than 15, 14, 13, 12, 11, 10, 9, 8, 7, 6, 5, or 4 genetic alterations, as compared to a native microbial cell. In various embodiments, microbial cells engineered for histamine production can have a number of genetic alterations falling within the any of the following illustrative ranges: 1-10, 1-9, 1-8, 2-7, 2-6, 2-5, 2-4, 2-3, 3-7, 3-6, 3-5, 3-4, etc.
In some embodiments, an engineered microbial cell expresses at least one heterologous histamine decarboxylase, such as in the case of a microbial host cell that does not naturally produce histamine. In various embodiments, the microbial cell can include and express, for example: (1) a single heterologous histamine decarboxylase gene, (2) two or more heterologous histamine decarboxylase genes, which can be the same or different (in other words, multiple copies of the same heterologous histamine decarboxylase genes can be introduced or multiple, different heterologous histamine decarboxylase genes can be introduced), (3) a single heterologous histamine decarboxylase gene that is not native to the cell and one or more additional copies of an native histamine decarboxylase gene, or (4) two or more non-native histamine decarboxylase genes, which can be the same or different, and one or more additional copies of an native histamine decarboxylase gene.
This engineered host cell can include at least one additional genetic alteration that increases flux through the pathway leading to the production of histidine (the immediate precursor of histamine). These “upstream” enzymes in the pathway include: an ATP phosphoribosyltransferase, a phosphoribosyl-ATP pyrophosphatase, a phosphoribosyl-AMP cyclohydrolase, a 5′ProFAR isomerase, an imidazole-glycerol phosphate synthase, an imidazole-glycerol phosphate dehydratase, a histidinol-phosphate aminotransferase, a histidinol-phosphate phosphatase, histidinol dehydrogenase, and a ribose phosphate pyrophosphokinase, including any isoforms, paralogs, or orthologs having these enzymatic activities (which as those of skill in the art readily appreciate may be known by different names). The at least one additional alteration can increase the activity of the upstream pathway enzyme(s) by any available means, e.g., by: (1) modulating the expression or activity of the native enzyme(s), (2) expressing one or more additional copies of the genes for the native enzymes, and/or (3) expressing one or more copies of the genes for one or more non-native enzymes.
In some embodiments, increased flux through the pathway can be achieved by expressing one or more genes encoding a feedback-deregulated enzyme, as discussed above. For example, the engineered host cell can include and express one or more feedback-deregulated ATP phosphoribosyltransferase genes.
The engineered microbial cells can contain introduced genes that have a native nucleotide sequence or that differ from native. For example, the native nucleotide sequence can be codon-optimized for expression in a particular host cell. The amino acid sequences encoded by any of these introduced genes can be native or can differ from native. In various embodiments, the amino acid sequences have at least 60 percent, 70 percent, 75 percent, 80 percent, 85 percent, 90 percent, 95 percent or 100 percent amino acid sequence identity with a native amino acid sequence.
In some embodiments, increased availability of precursors to histamine can be achieved by reducing the expression or activity of enzymes that consume one or more histamine pathway precursors, such as an enolase, a pyruvate dehydrogenase, a pentose phosphate pathway sugar isomerase, a transaldolase, a transketolase, a ribulose-5-phosphate epimerase, and a aribulose-5-phosphate isomerase. For example, the engineered host cell can include one or more promoter swaps to down-regulate expression of any of these enzymes and/or can have their genes deleted to eliminate their expression entirely.
The approach described herein has been carried out in bacterial cells, namely C. glutamicum and B. subtilis (prokaryotes) and in fungal cells, namely the yeasts S. cerevisiae and Y. lypolytica (eukaryotes). (See Examples 1 and 2.)
Illustrative Engineered Yeast Cells
In certain embodiments, the engineered yeast (e.g., S. cerevisiae) cell expresses a heterologous histamine decarboxylase having at least 70 percent, 75 percent, 80 percent, 85 percent, 90 percent, 95 percent or 100 percent amino acid sequence identity to a histamine decarboxylase from Chromobacterium sp. LK1 (e.g., SEQ ID NO:6). In particular embodiments, the Chromobacterium sp. LK1 histamine decarboxylase can include SEQ ID NO:6. The engineered yeast (e.g., S. cerevisiae) cell can also express a heterologous ATP phosphoribosyltransferase having at least 70 percent, 75 percent, 80 percent, 85 percent, 90 percent, 95 percent or 100 percent amino acid sequence identity with an ATP phosphoribosyltransferase from S. cerevisiae (SEQ ID NO:3). In particular embodiments, the S. cerevisiae ATP phosphoribosyltransferase includes SEQ ID NO:3.
In certain embodiments, the engineered yeast (e.g., Y. lipolytica) cell expresses a heterologous histamine decarboxylase having at least 70 percent, 75 percent, 80 percent, 85 percent, 90 percent, 95 percent or 100 percent amino acid sequence identity to a histamine decarboxylase from Acinetobacter baumannii strain AB0057 (e.g., SEQ ID NO:1). In particular embodiments, the Acinetobacter baumannii strain AB0057 histamine decarboxylase can include SEQ ID NO:1. The engineered yeast (e.g., Y. lipolytica) cell can also express a heterologous ATP phosphoribosyltransferase having at least 70 percent, 75 percent, 80 percent, 85 percent, 90 percent, 95 percent or 100 percent amino acid sequence identity with an ATP phosphoribosyltransferase from S. cerevisiae S288c (SEQ ID NO:3). In particular embodiments, the S. cerevisiae S288c ATP phosphoribosyltransferase includes SEQ ID NO:3.
These may be the only genetic alterations of the engineered yeast cell, or the yeast cell can include one or more additional genetic alterations, as discussed more generally above.
For example, in particular embodiments, the engineered yeast S. cerevisiae cell described above additionally expresses a feedback deregulated variant of a C. glutamicum ATP phosphoribosyltransferase, which typically has at least 70 percent, 75 percent, 80 percent, 85 percent, 90 percent, or 95 percent amino acid sequence identity to a variant of a C. glutamicum ATP phosphoribosyltransferase containing the amino acid substitutions N215K, L231F, and T235A (SEQ ID NO:7) In particular embodiments, the C. glutamicum ATP phosphoribosyltransferase variant can include SEQ ID NO:7.
Illustrative Engineered Bacterial Cells
In certain embodiments, the engineered bacterial (e.g., C. glutamicum) cell expresses a heterologous histamine decarboxylase having at least 70 percent, 75 percent, 80 percent, 85 percent, 90 percent, 95 percent or 100 percent amino acid sequence identity to a histamine decarboxylase from Acinetobacter baumannii (e.g., SEQ ID NO:1). In particular embodiments, the Acinetobacter baumannii histamine decarboxylase can include SEQ ID NO:1. The engineered bacterial (e.g., C. glutamicum) cell can also express a heterologous ATP phosphoribosyltransferase having at least 70 percent, 75 percent, 80 percent, 85 percent, 90 percent, 95 percent or 100 percent amino acid sequence identity with an ATP phosphoribosyltransferase from Saccharomyces cerevisiae S288c (SEQ ID NO:3). In particular embodiments, the S. cerevisiae S288c ATP phosphoribosyltransferase includes SEQ ID NO:3. In some embodiments, the engineered bacterial (e.g., C. glutamicum) cell expresses, instead of the ATP phosphoribosyltransferase, an imidazole-glycerol phosphate dehydratase having at least 70 percent, 75 percent, 80 percent, 85 percent, 90 percent, 95 percent or 100 percent amino acid sequence identity to an imidazole-glycerol phosphate dehydratase from C. glutamicum (SEQ ID NO:2). In particular embodiments, the C. glutamicum imidazole-glycerol phosphate dehydratase includes SEQ ID NO:2.
In certain embodiments, the engineered bacterial (e.g., B. subtilis) cell expresses a heterologous histamine decarboxylase having at least 70 percent, 75 percent, 80 percent, 85 percent, 90 percent, 95 percent or 100 percent amino acid sequence identity to a histamine decarboxylase from Lactobacillus sp. (strain 30a) (e.g., SEQ ID NO:4). In particular embodiments, the Lactobacillus sp. (strain 30a) histamine decarboxylase can include SEQ ID NO:4. The engineered bacterial (e.g., B. subtilis) cell can also express a heterologous ATP phosphoribosyltransferase having at least 70 percent, 75 percent, 80 percent, 85 percent, 90 percent, 95 percent or 100 percent amino acid sequence identity with an ATP phosphoribosyltransferase from Salmonella typhimurium LT2 (SEQ ID NO:5). In particular embodiments, the Salmonella typhimurium LT2 ATP phosphoribosyltransferase includes SEQ ID NO:5.
Any of the microbial cells described herein can be cultured, e.g., for maintenance, growth, and/or histamine production.
In some embodiments, the cultures are grown to an optical density at 600 nm of 10-500, such as an optical density of 50-150.
In various embodiments, the cultures include produced histamine at titers of at least 10, 25, 50, 75, 100, 200, 300, 400, 500, 600, 700, 800, or 900 μg/L, or at least 1, 10, 50, 75, 100, 200, 300, 400, 500, 600, 700, 800, or 900 mg/L or at least 1, 1.5, 2, 2.5, 3, 3.5, 4, 4.5, 5, 10, 20, 50 g/L. In various embodiments, the titer is in the range of 10 μg/L to 10 g/L, 25 μg/L to 20 g/L, 100 μg/L to 10 g/L, 200 μg/L to 5 g/L, 500 μg/L to 4 g/L, 1 mg/L to 3 g/L, 500 mg/L to 2 g/L or any range bounded by any of the values listed above.
Culture Media
Microbial cells can be cultured in any suitable medium including, but not limited to, a minimal medium, i.e., one containing the minimum nutrients possible for cell growth. Minimal medium typically contains: (1) a carbon source for microbial growth; (2) salts, which may depend on the particular microbial cell and growing conditions; and (3) water. Suitable media can also include any combination of the following: a nitrogen source for growth and product formation, a sulfur source for growth, a phosphate source for growth, metal salts for growth, vitamins for growth, and other cofactors for growth.
Any suitable carbon source can be used to cultivate the host cells. The term “carbon source” refers to one or more carbon-containing compounds capable of being metabolized by a microbial cell. In various embodiments, the carbon source is a carbohydrate (such as a monosaccharide, a disaccharide, an oligosaccharide, or a polysaccharide), or an invert sugar (e.g., enzymatically treated sucrose syrup). Illustrative monosaccharides include glucose (dextrose), fructose (levulose), and galactose; illustrative oligosaccharides include dextran or glucan, and illustrative polysaccharides include starch and cellulose. Suitable sugars include C6 sugars (e.g., fructose, mannose, galactose, or glucose) and C5 sugars (e.g., xylose or arabinose). Other, less expensive carbon sources include sugar cane juice, beet juice, sorghum juice, and the like, any of which may, but need not be, fully or partially deionized.
The salts in a culture medium generally provide essential elements, such as magnesium, nitrogen, phosphorus, and sulfur to allow the cells to synthesize proteins and nucleic acids.
Minimal medium can be supplemented with one or more selective agents, such as antibiotics.
To produce histamine, the culture medium can include, and/or is supplemented during culture with, glucose and/or a nitrogen source such as urea, an ammonium salt, ammonia, or any combination thereof.
Culture Conditions
Materials and methods suitable for the maintenance and growth of microbial cells are well known in the art. See, for example, U.S. Pub. Nos. 2009/0203102, 2010/0003716, and 2010/0048964, and International Pub. Nos. WO 2004/033646, WO 2009/076676, WO 2009/132220, and WO 2010/003007, Manual of Methods for General Bacteriology Gerhardt et al., eds), American Society for Microbiology, Washington, D.C. (1994) or Brock in Biotechnology: A Textbook of Industrial Microbiology, Second Edition (1989) Sinauer Associates, Inc., Sunderland, Mass.
In general, cells are grown and maintained at an appropriate temperature, gas mixture, and pH (such as about 20° C. to about 37° C., about 6% to about 84% CO2, and a pH between about 5 to about 9). In some aspects, cells are grown at 35° C. In certain embodiments, such as where thermophilic bacteria are used as the host cells, higher temperatures (e.g., 50° C.-75° C.) may be used. In some aspects, the pH ranges for fermentation are between about pH 5.0 to about pH 9.0 (such as about pH 6.0 to about pH 8.0 or about 6.5 to about 7.0). Cells can be grown under aerobic, anoxic, or anaerobic conditions based on the requirements of the particular cell.
Standard culture conditions and modes of fermentation, such as batch, fed-batch, or continuous fermentation that can be used are described in U.S. Publ. Nos. 2009/0203102, 2010/0003716, and 2010/0048964, and International Pub. Nos. WO 2009/076676, WO 2009/132220, and WO 2010/003007. Batch and Fed-Batch fermentations are common and well known in the art, and examples can be found in Brock, Biotechnology: A Textbook of Industrial Microbiology, Second Edition (1989) Sinauer Associates, Inc.
In some embodiments, the cells are cultured under limited sugar (e.g., glucose) conditions. In various embodiments, the amount of sugar that is added is less than or about 105% (such as about 100%, 90%, 80%, 70%, 60%, 50%, 40%, 30%, 20%, or 10%) of the amount of sugar that can be consumed by the cells. In particular embodiments, the amount of sugar that is added to the culture medium is approximately the same as the amount of sugar that is consumed by the cells during a specific period of time. In some embodiments, the rate of cell growth is controlled by limiting the amount of added sugar such that the cells grow at the rate that can be supported by the amount of sugar in the cell medium. In some embodiments, sugar does not accumulate during the time the cells are cultured. In various embodiments, the cells are cultured under limited sugar conditions for times greater than or about 1, 2, 3, 5, 10, 15, 20, 25, 30, 35, 40, 50, 60, or 70 hours or even up to about 5-10 days. In various embodiments, the cells are cultured under limited sugar conditions for greater than or about 5, 10, 15, 20, 25, 30, 35, 40, 50, 60, 70, 80, 90, 95, or 100% of the total length of time the cells are cultured. While not intending to be bound by any particular theory, it is believed that limited sugar conditions can allow more favorable regulation of the cells.
In some aspects, the cells are grown in batch culture. The cells can also be grown in fed-batch culture or in continuous culture. Additionally, the cells can be cultured in minimal medium, including, but not limited to, any of the minimal media described above. The minimal medium can be further supplemented with 1.0% (w/v) glucose (or any other six-carbon sugar) or less. Specifically, the minimal medium can be supplemented with 1% (w/v), 0.9% (w/v), 0.8% (w/v), 0.7% (w/v), 0.6% (w/v), 0.5% (w/v), 0.4% (w/v), 0.3% (w/v), 0.2% (w/v), or 0.1% (w/v) glucose. In some cultures, significantly higher levels of sugar (e.g., glucose) are used, e.g., at least 10% (w/v), 20% (w/v), 30% (w/v), 40% (w/v), 50% (w/v), 60% (w/v), 70% (w/v), or up to the solubility limit for the sugar in the medium. In some embodiments, the sugar levels falls within a range of any two of the above values, e.g.: 0.1-10% (w/v), 1.0-20% (w/v), 10-70% (w/v), 20-60% (w/v), or 30-50% (w/v). Furthermore, different sugar levels can be used for different phases of culturing. For fed-batch culture (e.g., of S. cerevisiae or C. glutamicum), the sugar level can be about 100-200 g/L (10-20% (w/v)) in the batch phase and then up to about 500-700 g/L (50-70% in the feed).
Additionally, the minimal medium can be supplemented 0.1% (w/v) or less yeast extract. Specifically, the minimal medium can be supplemented with 0.1% (w/v), 0.09% (w/v), 0.08% (w/v), 0.07% (w/v), 0.06% (w/v), 0.05% (w/v), 0.04% (w/v), 0.03% (w/v), 0.02% (w/v), or 0.01% (w/v) yeast extract. Alternatively, the minimal medium can be supplemented with 1% (w/v), 0.9% (w/v), 0.8% (w/v), 0.7% (w/v), 0.6% (w/v), 0.5% (w/v), 0.4% (w/v), 0.3% (w/v), 0.2% (w/v), or 0.1% (w/v) glucose and with 0.1% (w/v), 0.09% (w/v), 0.08% (w/v), 0.07% (w/v), 0.06% (w/v), 0.05% (w/v), 0.04% (w/v), 0.03% (w/v), or 0.02% (w/v) yeast extract. In some cultures, significantly higher levels of yeast extract can be used, e.g., at least 1.5% (w/v), 2.0% (w/v), 2.5% (w/v), or 3% (w/v). In some cultures (e.g., of S. cerevisiae or C. glutamicum), the yeast extract level falls within a range of any two of the above values, e.g.: 0.5-3.0% (w/v), 1.0-2.5% (w/v), or 1.5-2.0% (w/v).
Illustrative materials and methods suitable for the maintenance and growth of the engineered microbial cells described herein can be found below in Example 1.
Any of the methods described herein may further include a step of recovering histamine. In some embodiments, the produced histamine contained in a so-called harvest stream is recovered/harvested from the production vessel. The harvest stream may include, for instance, cell-free or cell-containing aqueous solution coming from the production vessel, which contains histamine as a result of the conversion of production substrate by the resting cells in the production vessel. Cells still present in the harvest stream may be separated from the histamine by any operations known in the art, such as for instance filtration, centrifugation, decantation, membrane crossflow ultrafiltration or microfiltration, tangential flow ultrafiltration or microfiltration or dead end filtration. After this cell separation operation, the harvest stream is essentially free of cells.
Further steps of separation and/or purification of the produced histamine from other components contained in the harvest stream, i.e., so-called downstream processing steps may optionally be carried out. These steps may include any means known to a skilled person, such as, for instance, concentration, extraction, crystallization, precipitation, adsorption, ion exchange, and/or chromatography. Any of these procedures can be used alone or in combination to purify histamine. Further purification steps can include one or more of, e.g., concentration, crystallization, precipitation, washing and drying, treatment with activated carbon, ion exchange, nanofiltration, and/or re-crystallization. The design of a suitable purification protocol may depend on the cells, the culture medium, the size of the culture, the production vessel, etc. and is within the level of skill in the art.
The following examples are given for the purpose of illustrating various embodiments of the disclosure and are not meant to limit the present disclosure in any fashion. Changes therein and other uses which are encompassed within the spirit of the disclosure, as defined by the scope of the claims, will be identifiable to those skilled in the art.
Plasmid/DNA Design
All strains tested for this work were transformed with plasmid DNA designed using proprietary software. Plasmid designs were specific to each of the host organisms engineered in this work. The plasmid DNA was physically constructed by a standard DNA assembly method. This plasmid DNA was then used to integrate metabolic pathway inserts by one of two host-specific methods, each described below.
C. glutamicum Pathway Integration
A “loop-in, single-crossover” genomic integration strategy has been developed to engineer C. glutamicum strains.
Loop-in, loop-out constructs (shown under the heading “Loop-in, loop-out) contained two 2-kb homology arms (5′ and 3′ arms), gene(s) of interest (arrows), a positive selection marker (denoted “Marker”), and a counter-selection marker. Similar to “loop-in” only constructs, a single crossover event integrated the plasmid into the chromosome of C. glutamicum. Note: only one of two possible integrations is shown here. Correct genomic integration was confirmed by colony PCR and counter-selection was applied so that the plasmid backbone and counter-selection marker could be excised. This results in one of two possibilities: reversion to wild-type (lower left box) or the desired pathway integration (lower right box). Again, correct genomic loop-out is confirmed by colony PCR. (Abbreviations: Primers: UF=upstream forward, DR=downstream reverse, IR=internal reverse, IF=internal forward.)
S. cerevisiae Pathway Integration
A “split-marker, double-crossover” genomic integration strategy has been developed to engineer S. cerevisiae strains.
Cell Culture
The workflow established for S. cerevisiae involved a hit-picking step that consolidated successfully built strains using an automated workflow that randomized strains across the plate. For each strain that was successfully built, up to four replicates were tested from distinct colonies to test colony-to-colony variation and other process variation. If fewer than four colonies were obtained, the existing colonies were replicated so that at least four wells were tested from each desired genotype.
The colonies were consolidated into 96-well plates with selective medium (SD-ura for S. cerevisiae) and cultivated for two days until saturation and then frozen with 16.6% glycerol at −80° C. for storage. The frozen glycerol stocks were then used to inoculate a seed stage in minimal media with a low level of amino acids to help with growth and recovery from freezing. The seed plates were grown at 30° C. for 1-2 days. The seed plates were then used to inoculate a main cultivation plate with minimal medium and grown for 48-88 hours. Plates were removed at the desired time points and tested for cell density (OD600), viability and glucose, supernatant samples stored for LC-MS analysis for product of interest.
Cell Density
Cell density was measured using a spectrophotometric assay detecting absorbance of each well at 600 nm. Robotics were used to transfer fixed amounts of culture from each cultivation plate into an assay plate, followed by mixing with 175 mM sodium phosphate (pH 7.0) to generate a 10-fold dilution. The assay plates were measured using a Tecan M1000 spectrophotometer and assay data uploaded to a LIMS database. A non-inoculated control was used to subtract background absorbance. Cell growth was monitored by inoculating multiple plates at each stage, and then sacrificing an entire plate at each time point.
To minimize settling of cells while handling large number of plates (which could result in a non-representative sample during measurement) each plate was shaken for 10-15 seconds before each read. Wide variations in cell density within a plate may also lead to absorbance measurements outside of the linear range of detection, resulting in underestimate of higher OD cultures. In general, the tested strains so far have not varied significantly enough for this be a concern.
Liquid-Solid Separation
To harvest extracellular samples for analysis by LC-MS, liquid and solid phases were separated via centrifugation. Cultivation plates were centrifuged at 2000 rpm for 4 minutes, and the supernatant was transferred to destination plates using robotics. 75 μL of supernatant was transferred to each plate, with one stored at 4° C., and the second stored at 80° C. for long-term storage.
First-Round Genetic Engineering Results in Corynebacteria glutamicum and Saccharomyces cerevisiae
A library approach was taken to screen heterologous pathway enzymes to establish the histamine pathway. For histidine decarboxylase, 18 heterologous sequences were tested from Bacteria, Archaea, Viridiplantae, Vertebrata, Metazoa, and Arthropoda sources listed in Table 1. The histidine decarboxylases were codon-optimized and expressed in both Saccharomyces cerevisiae and Corynebacteria glutamicum hosts.
Histidine biosynthesis is subject to feedback inhibition, therefore a feedback deregulated ATP phosphoribosyltransferase was tested with the histidine decarboxylases to improve production of histidine, the substrate for histidine decarboxylase. The ATP phosphoribosyltransferases tested were from Salmonella typhimurium and Corynebacteria glutamicum, harboring known deletions and point mutations that render them resistant to feedback inhibition.
First-round genetic engineering results are shown in Table 1 and
Corynebacterium
glutamicum
Methanosarcina
barkeri str.
Methanosarcina
barkeri (strain
Lactobacillus sp.
Acinetobacter
baumannii
Methanosarcina
barkeri str.
Lactobacillus
Salmonella
typhimurium
Lactobacillus
Salmonella
typhimurium
Methanosarcina
Salmonella
barkeri (strain
typhimurium
Drosophila
Salmonella
melanogaster
typhimurium
Chromo-
Salmonella
bacterium
typhimurium
Methanosarcina
Salmonella
barkeri str.
typhimurium
Methanosarcina
Salmonella
barkeri str.
typhimurium
Methanosarcina
Salmonella
barkeri (strain
typhimurium
Methanosarcina
Salmonella
barkeri (strain
typhimurium
Lactobacillus sp.
Salmonella
typhimurium
Drosophila
Salmonella
melanogaster
typhimurium
Acinetobacter
Salmonella
baumannii (strain
typhimurium
Methanosarcina
Salmonella
barkeri str.
typhimurium
Saccharomyces
cerevisiae
Lactobacillus
Coryne-
bacterium
glutamicum
Solanum
Salmonella
lycopersicum
typhimurium
Mus musculus
Salmonella
typhimurium
Drosophila
Salmonella
melanogaster
typhimurium
Chromo-
Salmonella
bacterium
typhimurium
Methanosarcina
Coryne-
barkeri str.
bacterium
glutamicum
Methanosarcina
Salmonella
barkeri (strain
typhimurium
Lactobacillus
Salmonella
typhimurium
Mus musculus
Coryne-
bacterium
glutamicum
Drosophila
Salmonella
melanogaster
typhimurium
Chromo-
Coryne-
bacterium
bacterium
glutamicum
Methanosarcina
Salmonella
barkeri str.
typhimurium
Methanosarcina
Salmonella
barkeri
typhimurium
Lactobacillus
Coryne-
bacterium
glutamicum
Solanum
Salmonella
lycopersicum
typhimurium
Mus musculus
Salmonella
typhimurium
Methanosarcina
Coryne-
barkeri str.
bacterium
glutamicum
Methanosarcina
Salmonella
barkeri (strain
typhimurium
Lactobacillus
Salmonella
typhimurium
Second-Round Genetic Engineering Results in Corynebacteria glutamicum and Saccharomyces cerevisiae
A library approach was taken to improve histamine production by separately expressing each upstream pathway enzyme with a constitutive promoter to screen for the rate-limiting step. The histidine pathway enzymes screened are listed in Table 2. In addition, the enzymes in Table 2, the strains contained the best enzymes from first round: the Corynebacteria glutamicum host contains histidine decarboxylase (UniProt ID B71459) (SEQ ID NO: 1) and ATP phosphoribosyltransferase (UniProt ID P00499) (SEQ ID NO: 5) containing the deletion Q207-E208, and the Saccharomyces cerevisiae host contains histidine decarboxylase (UniProt ID J6KM89)(SEQ ID NO: 6) and ATP phosphoribosyltransferase (UniProt ID Q9Z472) (SEQ ID NO: 7) containing the amino acid substitutions N215K, L231F and T235A.
Second-round genetic engineering results are shown in Table 2 and
In C. glutamicum, a titer of 24 mg/L was achieved after two rounds of engineering from the integration of two genes: a histidine decarboxylase gene from Acinetobacter baumannii, and constitutive expression of an imidazoleglycerol-phosphate dehydratase from C. glutamicum.
In S. cerevisiae, a titer of 385 mg/L was achieved in two rounds of engineering from the integration of three genes: a histidine decarboxylase gene from Chromobacterium sp. LK1 (SEQ ID NO: 6), an ATP phosphoribosyltransferase from C. glutamicum containing the amino acid substitutions N215K, L23IF, and T235A (SEQ ID NO: 7), and a constitutively expressed ATP phosphoribosyltransferase from S. cerevisiae (SEQ ID NO: 3).
Corynebacteria glutamicum and Saccharomyces cerevisiae
Corynebacteria
glutamicum
Corynebacterium
glutamicum
Corynebacterium
glutamicum
Corynebacterium
glutamicum
Corynebacterium
glutamicum
Corynebacterium
glutamicum
Corynebacterium
glutamicum
Corynebacterium
glutamicum
Corynebacterium
glutamicum
Corynebacterium
glutamicum
Corynebacterium
glutamicum
Corynebacterium
glutamicum
Corynebacterium
glutamicum
Corynebacterium
glutamicum
Corynebacterium
glutamicum
Corynebacterium
glutamicum
Corynebacterium
glutamicum
Corynebacterium
glutamicum
Corynebacterium
glutamicum
Corynebacterium
glutamicum
Corynebacterium
glutamicum
Corynebacterium
glutamicum
Corynebacterium
glutamicum
Corynebacterium
glutamicum
Saccharomyces
cerevisiae
Saccharomyces
cerevisiae
Saccharomyces
cerevisiae
Saccharomyces
cerevisiae
Saccharomyces
cerevisiae
Saccharomyces
cerevisiae
Saccharomyces
cerevisiae
Saccharomyces
cerevisiae
Saccharomyces
cerevisiae
Saccharomyces
cerevisiae
Saccharomyces
cerevisiae
Saccharomyces
cerevisiae
Saccharomyces
cerevisiae
Saccharomyces
cerevisiae
Saccharomyces
cerevisiae
Saccharomyces
cerevisiae
Saccharomyces
cerevisiae
Third-Round Genetic Engineering Results in Saccharomyces cerevisiae
Histamine production was further pursued in S. cerevisiae, and we designed plasmids to integrate additional copies of upstream pathway genes expressed by a strong constitutive promoter to avoid native regulation of a gene (Table 3). An expanded search was undertaken to test additional histidine decarboxylases that have similar sequences to the enzymes initially identified as active (Table 3).
In parallel we pursued modulating native gene expression to further improve histamine production. Our engineering approach was to take a best S. cerevisiae strain from the second round and test either a strong or weak constitutive promoter in place of the native promoter. Gene targets for promoter changes were selected to redirect flux supply precursors to histidine. Strain designs being tested include designs for increasing pentose phosphate pathway flux by expressing a non-native feedback deregulated glucose-6-phosphate dehydrogenase (zwf) and decreasing the “lower” pentose phosphate pathway flux thru the sugar isomerase enzymes.
Promoter replacements for lower expression of genes that are thought to be essential (i.e., cannot be deleted), but were expected to increase the upper glycolysis metabolite pool available for histamine production, targeted: 1) enolase (Eno2), to reduce flux through lower glycolysis, 2) pyruvate dehydrogenase (PDH, Lpd1) for lower flux through the C3/C2 node, and 3) pentose phosphate pathway sugar isomerases, which use the histamine metabolite precursor ribose-5-phosphate (Tall). An illustrative list of promoter-swap (“proswap”) and deletion (“knockout”) targets in S. cerevisiae includes:
Promoters were selected based on expression data from Lee et al [7].
Additional genetic engineering results for S. cerevisiae are shown in Table 3 and
Improved titer was observed in strains that expressed each of the following enzymes from a strong constitutive promoter:
Lactobacillus
fructivorans
Aeromonas
salmonicida
Coryne-
Saccharo-
Esche-
bacterium
myces
richia
glutamicum
cerevisiae
coli
Escherichia
coli
Saccharo-
Saccharo-
Arabi-
myces
myces
dopsis
cerevisiae
cerevisiae
thaliana
Saccharo-
Saccharo-
myces
myces
cerevisiae
cerevisiae
Saccharo-
Saccharo-
Saccharo-
myces
myces
myces
cerevisiae
cerevisiae
cerevisiae
Saccharo-
Saccharo-
Saccharo-
myces
myces
myces
cerevisiae
cerevisiae
cerevisiae
Saccharo-
Saccharo-
Arabi-
myces
myces
dopsis
cerevisiae
cerevisiae
thaliana
Saccharo-
Esche-
myces
richia
cerevisiae
coli
Saccharo-
Saccharo-
Esche-
myces
myces
richia
cerevisiae
cerevisiae
coli
Saccharo-
myces
cerevisiae
Saccharo-
Saccharo-
myces
myces
cerevisiae
cerevisiae
Saccharo-
Saccharo-
Saccharo-
myces
myces
myces
cerevisiae
cerevisiae
cerevisiae
Saccharo-
myces
cerevisiae
Saccharo-
myces
cerevisiae
Saccharo-
myces
cerevisiae
Saccharo-
myces
cerevisiae
Saccharo-
myces
cerevisiae
Saccharo-
myces
cerevisiae
Saccharo-
myces
cerevisiae
Saccharo-
myces
cerevisiae
Coryne-
bacterium
glutamicum
Coryne-
bacterium
glutamicum
Coryne-
Saccharo-
bacterium
myces
glutamicum
cerevisiae
Coryne-
Saccharo-
Saccharo-
bacterium
myces
myces
glutamicum
cerevisiae
cerevisiae
Coryne-
Saccharo-
Saccharo-
bacterium
myces
myces
glutamicum
cerevisiae
cerevisiae
Coryne-
Saccharo-
Coryne-
bacterium
myces
bacterium
glutamicum
cerevisiae
gluta-
micum
Coryne-
Saccharo-
Coryne-
bacterium
myces
bacterium
glutamicum
cerevisiae
gluta-
micum
Oenococcus
oeni
oenos)
Lactobacillus
aviarius
Pseudo-
monas
Pseudo-
monas
rhizosphaerae
Pseudo-
monas putida
siderocap-
sulatus)
Chromo-
bacterium sp.
Citrobacter
pasteurii
Chromo-
bacterium
haemolyticum
Lactobacillus
Lactobacillus
reuteri
Histamine production was also tested in two additional hosts, Bacillus subtilus and Yarrowia lipolytica, which were engineered to express the enzymes from the best-performing Corynebacterium glutamicum and Saccharomyces cerevisiae strains.
Host evaluation designs were selected to express 1-3 enzymes and, each design was tested with four different codon optimizations based on the host organisms C. glutamicum, S. cerevisiae, B. subtilis, and Y. lipolytica. The codon optimizations tested were based on the Kazusa codon usage tables tabulated for each host for gene codon optimization (www.kazusa.or.jp/codon/).
Histamine production was demonstrated in Y. lipolytica (
In Y. lipolytica (
The second best-performing strain in Y. lipolytica also expressed the histidine decarboxylase from Acinetobacter baumannii strain AB0057 (UniProt ID B71459), where the DNA sequence was codon-optimized for Y. lipolytica, and the ATP phosphoribosyltransferase from Salmonella typhimurium LT2 (UniProt ID P00499), where the DNA was codon optimized for Y. lipolytica. Versions of these two genes were also tested where the DNA sequence was codon optimized for B. subtilis (which produced 0 titer), codon-optimized for S. cerevisiae (which produced 33 micrograms histamine) and codon-optimized using a combined codon table for S. cerevisiae and C. glutamicum (produced 97 mg/L histamine).
The third best-performing strain in Y. lipolytica produced 258 mg/L histamine and expressed the histidine decarboxylase from Chromobacterium sp. LK1 (UniProt ID A0A0J6KM89), where the DNA sequence was codon optimized for Y. lipolytica, and the ATP phosphoribosyltransferase from C. glutamicum ATCC 13032 (UniProt ID Q9Z472) harboring the amino acid substitutions N215K, L23IF, T235A (SEQ ID NO: 7), where the DNA sequence was codon-optimized for Y. lipolytica (SEQ ID NO: 64). Versions of these two genes were also tested where the DNA sequences were codon-optimized for S. cerevisiae (SEQ ID NO: 65, 66) or B. subtilis (SEQ ID NO: 67, 68), and these Y. lipolytica strains produced 1.8 mg/L and 0.3 mg/L, respectively. Accordingly, codon-optimization of genes affects expression in Y. lipolytica.
In B. subtilis (
The host evaluation designs were also tested in S. cerevisiae and C. glutamicum. In S. cerevisiae (
In C. glutamicum (
The second best-performing strain in C. glutamicum produced 15 mg/L histamine and also expressed a histidine decarboxylase from Acinetobacter baumannii strain AB0057 (UniProt ID B7I459) (SEQ ID NO: 1), where the DNA sequence was codon optimized for Y. lipolytica (SEQ ID NO: 52), and an ATP phosphoribosyltransferase from Salmonella typhimurium LT2 (UniProt ID P00499) (SEQ ID NO: 5), where the DNA was codon optimized for Y. lipolytica (SEQ ID NO: 58). These same two genes were also tested, where the DNA sequences were codon-optimized for B. subtilis (SEQ ID NO: 54, 59) (which produced 8 mg/L histamine) or codon-optimized for S. cerevisiae (SEQ ID NO: 56, 60)(which produced 9.3 mg/L histamine).
Since the best performing strain is in the host Y. lipolytica, further strain improvements can be pursued in this host organism. Designs that can further enhance histamine production in Y. lipolytica include:
Three improvement rounds of genetic engineering were carried out in Yarrowia lipolytica.
First-Improvement Round Genetic Engineering in Yarrowia lipolytica
Strategy: Improve flux into histidine and then histamine by overexpression of two enzymes.
Acinetobacter
Yarrowia
baumannii
lypolytica
Saccharomyces
Yarrowia
cerevisiae
lypolytica
Summary: ATP phosphoribosyltranslerase catalyzes the first committed step of histidine biosynthesis pathway. This enzyme would be allosterically feedback-inhibited by histidine and competitively inhibited by AMP and ADP. The results did not indicate activity and/or inhibition of P00498.
Second-Improvement Round Genetic Engineering in Yarrowia lipolytica
Strategy: Overexpression of one enzyme. The final step of histamine biosynthesis was enhanced by utilizing the best first-round histidine decarboxylase which was modified to include a solubility tag to improve protein folding.
Acinetobacter
Yarrowia
baumannii
lypolytica
Summary: The histidine decarboxylase used for the second round of genetic engineering was the same as for the first round, although the codon optimization was different. Furthermore, an N-terminal solubility tag (MQYKLALNGKTLKGETTTEAVDAATAEKVFKQYANDNGVDGEWTYDDATKTFT VT, SEQ ID NO:142) was included in the second-round enzyme.
Third-Improvement Round Genetic Engineering in Yarrowia lipolytica
Strategy: Overexpression of two enzymes in pathways upstream of histidine biosynthesis to improve flux into phosphoribosyl pyrophosphate (PRPP).
Bacillus
Yarrowia
amyloliquefaciens
lypolytica
Corynebacterium
Yarrowia
glutamicum
lypolytica
Summary: Ribose-phosphate pyrophosphokinase is competitively inhibited ADP. The L135I mutation at the ATP binding site on the enzyme relieves ADP inhibition. This strain expressed histamine at a titer of 1.68 g/L of culture medium.
Yarrowia
lipolytica
Acinetobacter
Bacillus
Saccharomyces
Bacillus
baumannii
subtilis
cerevisiae
subtilis
Acinetobacter
Saccharo-
Saccharomyces
Saccharo-
baumannii
myces
cerevisiae
myces
cerevisiae
cerevisiae
Acinetobacter
Yarrowia
Saccharomyces
Yarrowia
baumannii
lipolytica
cerevisiae
lipolytica
Lactobacillus
Bacillus
Salmonella
Bacillus
subtilis
typhimurium
subtilis
Lactobacillus
Saccharo-
Salmonella
Saccharo-
myces
typhimurium
myces
cerevisiae
cerevisiae
Lactobacillus
Yarrowia
Salmonella
Yarrowia
lipolytica
typhimurium
lipolytica
Chromo-
Bacillus
Corynebacterium
Bacillus
bacterium
subtilis
glutamicum
subtilis
Chromo-
Saccharo-
Corynebacterium
Saccharo-
bacterium
myces
glutamicum
myces
cerevisiae
cerevisiae
Chromo-
Yarrowia
Corynebacterium
Yarrowia
bacterium
lipolytica
glutamicum
lipolytica
Acinetobacter
Bacillus
Salmonella
Bacillus
baumannii
subtilis
typhimurium
subtilis
Acinetobacter
Salmonella
baumannii
typhimurium
Acinetobacter
Saccharo-
Salmonella
Saccharo-
baumannii
myces
typhimurium
myces
cerevisiae
cerevisiae
Acinetobacter
Yarrowia
Salmonella
Yarrowia
baumannii
lipolytica
typhimurium
lipolytica
Lactobacillus
Bacillus
Corynebacterium
Bacillus
subtilis
glutamicum
subtilis
Lactobacillus
Corynebacterium
glutamicum
Lactobacillus
Saccharo-
Corynebacterium
Saccharo-
myces
glutamicum
myces
cerevisiae
Lactobacillus
Yarrowia
Corynebacterium
Yarrowia
lipolytica
glutamicum
lipolytica
Chromo-
Bacillus
Saccharomyces
Bacillus
bacterium
subtilis
cerevisiae
subtilis
Chromo-
Saccharomyces
bacterium
cerevisiae
Chromo-
Saccharo-
Saccharomyces
Saccharo-
bacterium
myces
cerevisiae
myces
cerevisiae
cerevisiae
Acinetobacter
Yarrowia
Saccharomyces
Yarrowia
baumannii
lipolytica
cerevisiae
lipolytica
Lactobacillus
Yarrowia
Salmonella
Yarrowia
lipolytica
typhimurium
lipolytica
Chromo-
Corynebacterium
bacterium
glutamicum
Lactobacillus
Bacillus
Corynebacterium
Bacillus
subtilis
glutamicum
subtilis
Lactobacillus
Corynebacterium
glutamicum
Lactobacillus
Yarrowia
Corynebacterium
Yarrowia
lipolytica
glutamicum
lipolytica
Acinetobacter
Bacillus
Saccharomyces
Bacillus
baumannii
subtilis
cerevisiae
subtilis
Acinetobacter
Saccharomyces
baumannii
cerevisiae
Acinetobacter
Saccharo-
Saccharomyces
Saccharo-
baumannii
myces
cerevisiae
myces
cerevisiae
cerevisiae
Lactobacillus
Bacillus
Salmonella
Bacillus
subtilis
typhimurium
subtilis
Lactobacillus
Salmonella
typhimurium
Lactobacillus
Saccharo-
Salmonella
Saccharo-
myces
typhimurium
myces
cerevisiae
cerevisiae
Chromo-
Bacillus
Corynebacterium
Bacillus
bacterium
subtilis
glutamicum
subtilis
Chromo-
Saccharo-
Corynebacterium
Saccharo-
bacterium
myces
glutamicum
myces
cerevisiae
cerevisiae
Chromo-
Yarrowia
Corynebacterium
Yarrowia
bacterium
lipolytica
glutamicum
lipolytica
Acinetobacter
Bacillus
Salmonella
Bacillus
baumannii
subtilis
typhimurium
subtilis
Acinetobacter
Salmonella
baumannii
typhimurium
Acinetobacter
Saccharo-
Salmonella
Saccharo-
baumannii
myces
typhimurium
myces
cerevisiae
cerevisiae
Acinetobacter
Yarrowia
Salmonella
Yarrowia
baumannii
lipolytica
typhimurium
lipolytica
Lactobacillus
Saccharo-
Corynebacterium
Saccharo-
myces
glutamicum
myces
cerevisiae
cerevisiae
Chromo-
Bacillus
Saccharomyces
Bacillus
bacterium
subtilis
cerevisiae
subtilis
Chromo-
Saccharomyces
bacterium
cerevisiae
Chromo-
Saccharo-
Saccharomyces
Saccharo-
bacterium
myces
cerevisiae
myces
cerevisiae
cerevisiae
Chromo-
Yarrowia
Saccharomyces
Yarrowia
bacterium
lipolytica
cerevisiae
lipolytica
Chromo-
Corynebacterium
bacterium
glutamicum
Saccharomyces
cerevisiae
Lactobacillus
Bacillus
Salmonella
Bacillus
subtilis
typhimurium
subtilis
Lactobacillus
Saccharo-
Salmonella
Saccharo-
myces
typhimurium
myces
cerevisiae
cerevisiae
Lactobacillus
Yarrowia
Salmonella
Yarrowia
lipolytica
typhimurium
lipolytica
Chromo-
Bacillus
Corynebacterium
Bacillus
bacterium
subtilis
glutamicum
subtilis
Chromo-
Corynebacterium
bacterium
glutamicum
Chromo-
Saccharo-
Corynebacterium
Saccharo-
bacterium
myces
glutamicum
myces
cerevisiae
cerevisiae
Chromo-
Yarrowia
Corynebacterium
Yarrowia
bacterium
lipolytica
glutamicum
lipolytica
Acinetobacter
Bacillus
Salmonella
Bacillus
baumannii
subtilis
typhimurium
subtilis
Acinetobacter
Yarrowia
Salmonella
Yarrowia
baumannii
lipolytica
typhimurium
lipolytica
Lactobacillus
Bacillus
Corynebacterium
Bacillus
subtilis
glutamicum
subtilis
Lactobacillus
Corynebacterium
glutamicum
Lactobacillus
Saccharo-
Corynebacterium
Saccharo-
myces
glutamicum
myces
cerevisiae
cerevisiae
Lactobacillus
Yarrowia
Corynebacterium
Yarrowia
lipolytica
glutamicum
lipolytica
Chromo-
Bacillus
Saccharomyces
Bacillus
bacterium
subtilis
cerevisiae
subtilis
Chromo-
Saccharo-
Saccharomyces
Saccharo-
bacterium
myces
cerevisiae
myces
cerevisiae
cerevisiae
Chromo-
Yarrowia
Saccharomyces
Yarrowia
bacterium
lipolytica
cerevisiae
lipolytica
Acinetobacter
Bacillus
Saccharomyces
Bacillus
baumannii
subtilis
cerevisiae
subtilis
Acinetobacter
Saccharomyces
baumannii
cerevisiae
Acinetobacter
Saccharo-
Saccharomyces
Saccharo-
baumannii
myces
cerevisiae
myces
cerevisiae
cerevisiae
Acinetobacter
Yarrowia
Saccharomyces
Yarrowia
baumannii
lipolytica
cerevisiae
lipolytica
Lactobacillus
Bacillus
Salmonella
Bacillus
subtilis
typhimurium
subtilis
Lactobacillus
Saccharo-
Salmonella
Saccharo-
myces
typhimurium
myces
cerevisiae
cerevisiae
Lactobacillus
Yarrowia
Salmonella
Yarrowia
lipolytica
typhimurium
lipolytica
Chromo-
Bacillus
Corynebacterium
Bacillus
bacterium
subtilis
glutamicum
subtilis
Chromo-
Saccharo-
Corynebacterium
Saccharo-
bacterium
myces
glutamicum
myces
cerevisiae
cerevisiae
Chromo-
Yarrowia
Corynebacterium
Yarrowia
bacterium
lipolytica
glutamicum
lipolytica
Acinetobacter
Bacillus
Salmonella
Bacillus
baumannii
subtilis
typhimurium
subtilis
Acinetobacter
Saccharo-
Salmonella
Saccharo-
baumannii
myces
typhimurium
myces
cerevisiae
cerevisiae
Acinetobacter
Yarrowia
Salmonella
Yarrowia
baumannii
lipolytica
typhimurium
lipolytica
Lactobacillus
Bacillus
Corynebacterium
Bacillus
subtilis
glutamicum
subtilis
Lactobacillus
Saccharo-
Corynebacterium
Saccharo-
myces
glutamicum
myces
cerevisiae
cerevisiae
Lactobacillus
Yarrowia
Corynebacterium
Yarrowia
lipolytica
glutamicum
lipolytica
Chromo-
Bacillus
Saccharomyces
Bacillus
bacterium
subtilis
cerevisiae
subtilis
This application is a continuation of U.S. Non-provisional application Ser. No. 17/048,553, filed Oct. 16, 2020, which is a U.S. 371 National Phase of PCT International application no. PCT/US2019/028401, filed Apr. 19, 2019, which claims the benefit of U.S. provisional application No. 62/660,875, filed Apr. 20, 2018, each of which is hereby incorporated by reference in its entirety.
This invention was made with Government support under Agreement No. HR0011-15-9-0014, awarded by DARPA. The Government has certain rights in the invention.
| Number | Date | Country | |
|---|---|---|---|
| 62660875 | Apr 2018 | US |
| Number | Date | Country | |
|---|---|---|---|
| Parent | 17048553 | Oct 2020 | US |
| Child | 18349895 | US |
