MINEs: open access databases of computationally predicted enzyme promiscuity products for untargeted metabolomics

Jeffryes, James G.; Colastani, Ricardo L; Elbadawi-Sidhu, Mona; Kind, Tobias; Niehaus, Thomas D.; Broadbelt, Linda J.; Hanson, Andrew D.; Fiehn, Oliver; Tyo, Keith E.J.; Henry, Christopher S.

doi:10.1186/s13321-015-0087-1

“…One solution to increase mass spectral library coverage is to use quantum chemical simulations predict electron ionization mass spectra9 or to utilize novel machine learning methods to improve compound identification10. This can also include novel metabolic compounds that can be expected to exist from known metabolic transformations11.…”

Section: Discussionmentioning

confidence: 99%

Interstitial Cystitis-Associated Urinary Metabolites Identified by Mass-Spectrometry Based Metabolomics Analysis

Kind

¹

,

Cho

²

,

Park³

et al. 2016

Sci Rep

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This study on interstitial cystitis (IC) aims to identify a unique urine metabolomic profile associated with IC, which can be defined as an unpleasant sensation including pain and discomfort related to the urinary bladder, without infection or other identifiable causes. Although the burden of IC on the American public is immense in both human and financial terms, there is no clear diagnostic test for IC, but rather it is a disease of exclusion. Very little is known about the clinically useful urinary biomarkers of IC, which are desperately needed. Untargeted comprehensive metabolomic profiling was performed using gas-chromatography/mass-spectrometry to compare urine specimens of IC patients or health donors. The study profiled 200 known and 290 unknown metabolites. The majority of the thirty significantly changed metabolites before false discovery rate correction were unknown compounds. Partial least square discriminant analysis clearly separated IC patients from controls. The high number of unknown compounds hinders useful biological interpretation of such predictive models. Given that urine analyses have great potential to be adapted in clinical practice, research has to be focused on the identification of unknown compounds to uncover important clues about underlying disease mechanisms.

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“…One solution to increase mass spectral library coverage is to use quantum chemical simulations predict electron ionization mass spectra 9 or to utilize novel machine learning methods to improve compound identification 10 . This can also include novel metabolic compounds that can be expected to exist from known metabolic transformations 11 . Histidine, one of essential amino acids in humans, is a known precursor of the neurotransmitter histamine.…”

Section: Discussionmentioning

confidence: 99%

<strong>Interstitial Cystitis-Associated Urinary Metabolites </strong><strong>Identified by Mass-Spectrometry Based Metabolomics Analysis</strong>

Kim

¹

2016

Proceedings of the 1st International Electronic Conference on Metabolomics

0

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This study on interstitial cystitis (IC) aims to identify a unique urine metabolomic profile associated with IC, which can be defined as an unpleasant sensation including pain and discomfort related to the urinary bladder, without infection or other identifiable causes. Although the burden of IC on the American public is immense in both human and financial terms, there is no clear diagnostic test for IC, but rather it is a disease of exclusion. Very little is known about the clinically useful urinary biomarkers of IC, which are desperately needed. Untargeted comprehensive metabolomic profiling was performed using gas-chromatography/mass-spectrometry to compare urine specimens of IC patients or health donors. The study profiled 200 known and 290 unknown metabolites. The majority of the thirty significantly changed metabolites before false discovery rate correction were unknown compounds. Partial least square discriminant analysis clearly separated IC patients from controls. The high number of unknown compounds hinders useful biological interpretation of such predictive models. Given that urine analyses have great potential to be adapted in clinical practice, research has to be focused on the identification of unknown compounds to uncover important clues about underlying disease mechanisms.More than 3-8 million women and 1-4 million men are diagnosed with Interstitial Cystitis (IC), also known as Painful Bladder Syndrome, in the US annually 1 . IC impacts health-related qualities of life immensely, and in some instances can be more debilitating than end-stage renal disease 2,3 . In spite of an increase in the number of diagnosed cases, objective diagnostic criteria are not consistently applied in general practice 4 . Some lower urinary tract symptoms, such as overactive bladder (OAB), have symptoms in common with IC, further complicating the diagnosis. Diagnosis of the disease has been dependent on clinical parameters (e.g. pain, urgency, and frequency) due to the lack of proper conventional markers (e.g. PSA for prostate cancer diagnosis) 3,5 . Diagnostic tests include urinalysis, urine culture, cystoscopy, bladder biopsy and hydrodistention of the bladder. Nonetheless, we still lack definite criteria for the disease. Estimates of the prevalence and natural history of IC still fluctuate widely because of different diagnostic standards, populations evaluated, and challenges inherent in following patients over time 6 . Thus, the identification of sensitive and non-invasive biomarkers has the potential to greatly improve the accuracy of an IC diagnosis. However, our current understanding of mechanisms involving pelvic pain is also unclear and fragmented.Urinary metabolites represent a signature of a subject's metabolic state and may convey critical information about the pathophysiology of disease. This may be especially true for pelvic disorders because urine is the body fluid most proximal to the urinary tract. Because metabolites vary in size, chemistry and physicochemical properties, a single platform has only a ...

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“…In one particularly impressive example, MS/MS spectra were predicted via CFM-ID for all of the compounds in the Dictionary of Natural Products [115]. By constructing a spectral similarity network and using sophisticated spectral matching comparisons it was possible to use this network of predicted MS/MS spectra to identify a number of previously unidentified compounds [155]. …”

Section: Future Perspectivesmentioning

confidence: 99%

“…A number of commercial tools now exist for calculating phase I metabolism and phase I metabolite structures using known structures as the starting point [156]. Software is also starting to appear to predict promiscuous enzyme products [155] and microbial biotransformations [157] from known structures. Given the existence of these tools, it seems that the next logical step would be to bring them together and to start creating a large database of biologically reasonable or biologically feasible metabolites.…”

Section: Future Perspectivesmentioning

confidence: 99%

Current and Future Perspectives on the Structural Identification of Small Molecules in Biological Systems

Dias

¹

,

Jones

²

,

Beale

³

et al. 2016

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Although significant advances have been made in recent years, the structural elucidation of small molecules continues to remain a challenging issue for metabolite profiling. Many metabolomic studies feature unknown compounds; sometimes even in the list of features identified as "statistically significant" in the study. Such metabolic "dark matter" means that much of the potential information collected by metabolomics studies is lost. Accurate structure elucidation allows researchers to identify these compounds. This in turn, facilitates downstream metabolite pathway analysis, and a better understanding of the underlying biology of the system under investigation. This review covers a range of methods for the structural elucidation of individual compounds, including those based on gas and liquid chromatography hyphenated to mass spectrometry, single and multi-dimensional nuclear magnetic resonance spectroscopy, and high-resolution mass spectrometry and includes discussion of data standardization. Future perspectives in structure elucidation are also discussed; with a focus on the potential development of instruments and techniques, in both nuclear magnetic resonance spectroscopy and mass spectrometry that, may help solve some of the current issues that are hampering the complete identification of metabolite structure and function.

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MINEs: open access databases of computationally predicted enzyme promiscuity products for untargeted metabolomics

Cited by 200 publications

References 47 publications

Interstitial Cystitis-Associated Urinary Metabolites Identified by Mass-Spectrometry Based Metabolomics Analysis

Interstitial Cystitis-Associated Urinary Metabolites Identified by Mass-Spectrometry Based Metabolomics Analysis

<strong>Interstitial Cystitis-Associated Urinary Metabolites </strong><strong>Identified by Mass-Spectrometry Based Metabolomics Analysis</strong>

Current and Future Perspectives on the Structural Identification of Small Molecules in Biological Systems

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