Difference between revisions of "Part:BBa K3140003"
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[[Image:T--Sydney Australia--SDS soluble PsiDKM.png|900px|thumb|none|'''Fig. 3''': Polyacrylamide gel electrophoresis image of soluble protein extract from uninduced and IPTG induced ''E. coli'' BL21(DE3)::pGro7 cells containing pET-28c(+):PsiD, pET-28c(+):PsiK, and pET-28c(+):PsiM, run on an Mini-PROTEAN® TGX Stain-Free™ precast gel (Bio-Rad) at 120V for 60 minutes.]]
 
[[Image:T--Sydney Australia--SDS soluble PsiDKM.png|900px|thumb|none|'''Fig. 3''': Polyacrylamide gel electrophoresis image of soluble protein extract from uninduced and IPTG induced ''E. coli'' BL21(DE3)::pGro7 cells containing pET-28c(+):PsiD, pET-28c(+):PsiK, and pET-28c(+):PsiM, run on an Mini-PROTEAN® TGX Stain-Free™ precast gel (Bio-Rad) at 120V for 60 minutes.]]
  
''In vivo'' expression of PsiM was confirmed by LC/MS. PsiD, PsiK, and PsiM were cloned into a pUS250 backbone as a gene cluster using Golden Gate cloning, yielding pUS387 ('''Fig. 4'''). Expression in pUS387 is driven by a class 1 integron gene cassette Pc promoter controlled by a cumate induction system. ''E. coli'' DH5α cells co-transformed with pUS387 and pGro7 were cultured in terrific broth (TB) supplemented with 4-hydroxytryptamine. Whole cell culture was subject to LC/MS.
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Further confirmation was gained by peptide mass fingerprinting. <<NATHAN GEL>>
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Matched peptides are shown below in red:
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MHIRNPYRDGVDYQALAEAFPALKPHVTVNSDNTTSIDFAVPEAQR<span style="color:red">'''LYTAALLHRDFGLTITLPEDRLCPTVPNRLNYVLWVEDILKVTSDALGLPDNR'''</span>QVKGIDIGTGASAIYPMLACSRFKTWSMVATEVDQKCIDTAR<span style="color:red">'''LNVIANNLQER'''</span>LAIIATSVDGPILVPLLQANSDFEYDFTMCNPPFYDGASDMQTSDAAK<span style="color:red">'''GFGFGVNAPHTGTVLEMATEGGESAFVAQMVR'''</span>ESLNLQTRCRWFTSNLGK<span style="color:red">'''LKSLYEIVGLLREHQISNYAINEYVQGATRRYAIAWSFIDVRLPDHLSRPSNPDLSSLF'''</span>
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However, ''in vivo'' activity of PsiM could not be confirmed by LC/MS. PsiD, PsiK, and PsiM were cloned into a pUS250 backbone as a gene cluster using Golden Gate cloning, yielding pUS387 ('''Fig. 4'''). Expression in pUS387 is driven by a class 1 integron gene cassette Pc promoter controlled by a cumate induction system. ''E. coli'' DH5α cells co-transformed with pUS387 and pGro7 were cultured in terrific broth (TB) supplemented with 4-hydroxytryptamine. Whole cell culture was subject to LC/MS.
  
 
[[Image:T--Sydney_Australia--pUS387_map.png|700px|frame|none|'''Fig. 4''': pUS387 plasmid map, showing PsiD, PsiK, and PsiM genes organised in a cluster, driven by a class 1 integron gene cassette Pc promoter, flanked by CuO, a cumate repressor binding operator.]]
 
[[Image:T--Sydney_Australia--pUS387_map.png|700px|frame|none|'''Fig. 4''': pUS387 plasmid map, showing PsiD, PsiK, and PsiM genes organised in a cluster, driven by a class 1 integron gene cassette Pc promoter, flanked by CuO, a cumate repressor binding operator.]]
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While ''in vitro'' activity of PsiM could not be conducted due to the lack of availability of reagent norbaeocystin, the ''in vivo'' activity of PsiM is confirmed by observation of PsiM product baeocystin ('''Fig. 5''').
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While ''in vitro'' activity of PsiM could not be conducted due to the lack of availability of reagent norbaeocystin, the ''in vivo'' activity of PsiM appeared to be confirmed by observation of PsiM product baeocystin ('''Fig. 5''').
  
 
[[Image:T--Sydney_Australia--baeo16_387_lcms.png|frame|none|'''Fig. 5''': Mass spectra obtained LC/MS of protein extract of ''E. coli'' DH5α co-transformed with pUS387 and pGro7, with the addition of 4-hydroxytryptamine. A peak at m/z = 271.08422 with chemical formula C10H14N2O4P was identified, matching PsiK product norbaeocystin.]]
 
[[Image:T--Sydney_Australia--baeo16_387_lcms.png|frame|none|'''Fig. 5''': Mass spectra obtained LC/MS of protein extract of ''E. coli'' DH5α co-transformed with pUS387 and pGro7, with the addition of 4-hydroxytryptamine. A peak at m/z = 271.08422 with chemical formula C10H14N2O4P was identified, matching PsiK product norbaeocystin.]]
  
Finally, we were able to confirm the identity of PsiM on a polyacrylamide gel ('''Fig. 6''') using peptide mass fingerprinting.
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However, pUS387 sequencing data showed a significant deletion in PsiM. This deletion was confirmed by agarose gel electrophoresis.
 
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[[Image:T--Sydney_Australia--peptide_gel.jpg|frame|none|'''Fig. 6''': Polyacrylamide gel prepared for peptide mass fingerprinting.]]
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Given these results, we conclude that we have successfully expressed the norbaeocystin methyltransferase PsiM from ''Psilocybe cubensis'' in ''Escherichia coli'' ''in vivo''.
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Given these results, we conclude that we have successfully expressed the norbaeocystin methyltransferase PsiM from ''Psilocybe cubensis'' in ''Escherichia coli'', but could not confirm activity either ''in vitro'' or ''in vivo''. Presence of baeocystin in pUS387 cell cultures may be due to an endogenous methyltransferase acting upon norbaeocystin.
  
 
<span class='h3bb'>'''Sequence and Features'''</span>
 
<span class='h3bb'>'''Sequence and Features'''</span>

Revision as of 06:51, 20 October 2019


PsiM - Norbaeocystin methyltransferase from Psilocybe cubensis

PsiM is a norbaeocystin methyltransferase, which catalyses the conversion of norbaeocystin to psilocybin.

Usage and Biology

The mechanism of psilocybin biosynthesis in Psilocybe sp. was recently elucidated by Fricke et al.[1], demonstrating that L-tryptophan proceeds through decarboxylation (mediated by PsiD), hydroxylation (mediated by PsiH), phosphorylation (mediated by PsiK), and finally N,N-dimethylation (mediated by PsiM) to yield psilocybin.

PsiM is a native enzyme obtained from Psilocybe cubensis, which is involved in the metabolic biosynthesis of psilocybin from tryptophan. It accepts norbaeocystin as a substrate to yield psilocybin through N,N-dimethylation (Fig. 1). In a native state, PsiM is a 309 amino acid protein (34.4 kDa) with a theoretical pI of 4.96 calculated with the ExPASy ProtParam tool[2].

Fig. 1: N,N-dimethylation of norbaeocystin to psilocybin, mediated by PsiM. Intermediates not shown. Two S-adenosyl-L-methionine moieties are consumed, releasing two S-sdenosyl-L-homocysteine moieties as a by-product. Source: KEGG

Heterologous expression of PsiM has been achieved in a T7 induction system using pET-28c(+) transformed into Escherichia coli BL21(DE3), co-transformed with chaperone plasmid pGro7 (Fig. 2), resulting in a 345 amino acid polypeptide, with a computed molecular weight of 38.2 kDa.

Fig. 2: pET-28c(+):PsiM plasmid map, showing C-terminal histidine tag, and T7 promoter under the control of the lac operator. Translated peptide is shown as the thin lime green arrow.

A band consistent with expression of PsiM in cells induced with IPTG was observed on polyacrylamide gel electrophoresis (Fig. 3).

Fig. 3: Polyacrylamide gel electrophoresis image of soluble protein extract from uninduced and IPTG induced E. coli BL21(DE3)::pGro7 cells containing pET-28c(+):PsiD, pET-28c(+):PsiK, and pET-28c(+):PsiM, run on an Mini-PROTEAN® TGX Stain-Free™ precast gel (Bio-Rad) at 120V for 60 minutes.

Further confirmation was gained by peptide mass fingerprinting. <<NATHAN GEL>>

Matched peptides are shown below in red:

MHIRNPYRDGVDYQALAEAFPALKPHVTVNSDNTTSIDFAVPEAQRLYTAALLHRDFGLTITLPEDRLCPTVPNRLNYVLWVEDILKVTSDALGLPDNRQVKGIDIGTGASAIYPMLACSRFKTWSMVATEVDQKCIDTARLNVIANNLQERLAIIATSVDGPILVPLLQANSDFEYDFTMCNPPFYDGASDMQTSDAAKGFGFGVNAPHTGTVLEMATEGGESAFVAQMVRESLNLQTRCRWFTSNLGKLKSLYEIVGLLREHQISNYAINEYVQGATRRYAIAWSFIDVRLPDHLSRPSNPDLSSLF




However, in vivo activity of PsiM could not be confirmed by LC/MS. PsiD, PsiK, and PsiM were cloned into a pUS250 backbone as a gene cluster using Golden Gate cloning, yielding pUS387 (Fig. 4). Expression in pUS387 is driven by a class 1 integron gene cassette Pc promoter controlled by a cumate induction system. E. coli DH5α cells co-transformed with pUS387 and pGro7 were cultured in terrific broth (TB) supplemented with 4-hydroxytryptamine. Whole cell culture was subject to LC/MS.

Fig. 4: pUS387 plasmid map, showing PsiD, PsiK, and PsiM genes organised in a cluster, driven by a class 1 integron gene cassette Pc promoter, flanked by CuO, a cumate repressor binding operator.
Table 1: Identified compounds in LC/MS of protein extract of E. coli DH5α co-transformed with pUS387 and pGro7, with the addition of 4-hydroxytryptamine.
Retention time (min) Signal/noise ratio Measured m/z Formula Ion identity
0.56 23.2 271.0817 C12H15O7 unknown
1.16 12.4 257.0689 C10H14N2O4P norbaeocystin
1.9 0.9 271.0844 C11H16N2O4P baeocystin
2.75 5.2 177.1023 C10H13N2O hydroxytryptamine
5.08 6.4 205.0972 C11H13N2O2 tryptophan
5.82 6.4 161.1074 C10H13N2 tryptamine
10.15 14.4 285.1335 C14H21O6 unknown
10.15 14.4 285.1335 C9H18N8OP unknown

While in vitro activity of PsiM could not be conducted due to the lack of availability of reagent norbaeocystin, the in vivo activity of PsiM appeared to be confirmed by observation of PsiM product baeocystin (Fig. 5).

Fig. 5: Mass spectra obtained LC/MS of protein extract of E. coli DH5α co-transformed with pUS387 and pGro7, with the addition of 4-hydroxytryptamine. A peak at m/z = 271.08422 with chemical formula C10H14N2O4P was identified, matching PsiK product norbaeocystin.

However, pUS387 sequencing data showed a significant deletion in PsiM. This deletion was confirmed by agarose gel electrophoresis.

Given these results, we conclude that we have successfully expressed the norbaeocystin methyltransferase PsiM from Psilocybe cubensis in Escherichia coli, but could not confirm activity either in vitro or in vivo. Presence of baeocystin in pUS387 cell cultures may be due to an endogenous methyltransferase acting upon norbaeocystin.

Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    COMPATIBLE WITH RFC[12]
  • 21
    COMPATIBLE WITH RFC[21]
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    COMPATIBLE WITH RFC[1000]


References

  1. Fricke, J., Blei, F. & Hoffmeister, D. Enzymatic Synthesis of Psilocybin. Angew Chem Int Ed Engl 56, 12352-12355 (2017).
  2. Artimo, P. et al. ExPASy: SIB bioinformatics resource portal. Nucleic Acids Res 40, W597-603 (2012).