Expression of rTSβ as a 5-fluorouracil resistance marker in patients with primary breast cancer

Kuo, Shou‐Jen; Wang, Hwei-Chung; Chow, Kuan‐Chih; Chiou, Shiow-Her; Chiang, Shu‐Fen; Lin, Tze–Yi; Chiang, I-Ping; Chen, Dar‐Ren

doi:10.3892/or.19.4.881

Cited by 5 publications

(11 citation statements)

References 27 publications

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“…In clinical studies, rTSβ was found to be expressed in breast cancer tissue but not the surrounding tissues. 8 Furthermore, a statistically significant correlation was found between the level of rTSβ expression and a decrease in the five year survival rate of colon cancer patients. 5 The 27 residue longer N-terminus of rTSγ, compared to rTSβ, is proposed to constitute a mitochondrial signaling sequence, 9 suggesting that rTSβ and rTSγ serve similar enzymatic functions.…”

Section: Introductionmentioning

confidence: 89%

Enzymatic and Structural Characterization of rTSγ Provides Insights into the Function of rTSβ

et al. 2014

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In humans, the gene encoding a reverse thymidylate synthase (rTS) is transcribed in the reverse direction of the gene encoding thymidylate synthase (TS) that is involved in DNA biosynthesis. Three isoforms are found: α, β, and γ, with the transcript of the α-isoform overlapping with that of TS. rTSβ has been of interest since the discovery of its overexpression in methotrexate and 5-fluorouracil resistant cell lines. Despite more than 20 years of study, none of the rTS isoforms have been biochemically or structurally characterized. In this study, we identified rTSγ as an l-fuconate dehydratase and determined its high-resolution crystal structure. Our data provide an explanation for the observed difference in enzymatic activities between rTSβ and rTSγ, enabling more informed proposals for the possible function of rTSβ in chemotherapeutic resistance.

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Section: Introductionmentioning

confidence: 89%

Enzymatic and Structural Characterization of rTSγ Provides Insights into the Function of rTSβ

et al. 2014

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“…The same group also reported a statistically significant decrease in five year survival of colon cancer patients with tumor hsENOSF1β expression compared to colon cancer patients without tumor hsENOSF1β expression [ 29 ]. Taken together, in vitro cell culture data [ 23 - 27 ] and human patient data [ 28 , 29 ] suggest a connection between hsENOSF1β expression and cancer.…”

Section: Introductionmentioning

confidence: 95%

“…In cell culture, hsENOSF1β expression appears to be regulated by environmental factors such as cell density, time in culture, and exposure to chemotherapy drugs that affect thymidylate synthase or folate pathway enzymes [ 23 - 27 ]. Using patient samples from a Taiwanese population, Kuo et al [ 28 ] showed that hsENOSF1β is expressed in breast tumor tissue and not surrounding tissue. The α or γ splice forms were not found in the patient samples [ 28 ].…”

Section: Introductionmentioning

confidence: 99%

“…Using patient samples from a Taiwanese population, Kuo et al [ 28 ] showed that hsENOSF1β is expressed in breast tumor tissue and not surrounding tissue. The α or γ splice forms were not found in the patient samples [ 28 ]. The same group also reported a statistically significant decrease in five year survival of colon cancer patients with tumor hsENOSF1β expression compared to colon cancer patients without tumor hsENOSF1β expression [ 29 ].…”

Section: Introductionmentioning

confidence: 99%

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Transient knockdown and overexpression reveal a developmental role for the zebrafish enosf1b gene

Finckbeiner

Carrington

et al. 2011

Cell Biosci

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BackgroundDespite detailed in vivo knowledge of glycolytic enolases and many bacterial non-enolase members of the superfamily, little is known about the in vivo function of vertebrate non-enolase enolase superfamily members (ENOSF1s). Results of previous studies suggest involvement of the β splice form of ENOSF1 in breast and colon cancers. This study used the zebrafish (Danio rerio) as a vertebrate model of ENOSF1β function.ResultsWhole mount in situ hybridization (WISH) showed that zebrafish ENOSF1β (enosf1b) is zygotic and expressed ubiquitously through the first 24 hours post fertilization (hpf). After 24 hpf, enosf1b expression is restricted to the notochord. Embryos injected with enosf1b-EGFP mRNA grew slower than EGFP mRNA-injected embryos but caught up to the EGFP-injected embryos by 48 hpf. Embryos injected with ATG or exon 10 enosf1b mRNA-targeting morpholinos had kinked notochords, shortened anterior-posterior axes, and circulatory edema. WISH for ntl or pax2a expression showed that embryos injected with either morpholino have deformed notochord and pronephros. TUNEL staining revealed increased apoptosis in the peri-notochord region.ConclusionsThis study is the first report of ENOSF1 function in a vertebrate and shows that ENOSF1 is required for embryonic development. Increased apoptosis following enosf1b knockdown suggests a potential survival advantage for increased ENOSF1β expression in human cancers.

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“…5‐FU undergoes complex anabolic and catabolic biotransformation. Gene products involved in this transformation include dihydropyrimidine dehydrogenase (DPD or DPYD ), which breaks down 5‐FU,84–88 and those drug targets (eg, thymidylate synthase [TS or TYMS ])89, 90 and methylenetetrahydrofolate reductase ( MTHFR ). Several of these genes have been shown to affect 5‐FU treatment outcomes.…”

Section: Examplesmentioning

confidence: 99%

Pharmacogenetics and pharmacogenomics of anticancer agents

Huang¹,

Ratain²

2009

CA: A Cancer Journal for Clinicians

130

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Large interindividual variation is observed in both the response and toxicity associated with anticancer therapy. The etiology of this variation is multifactorial, but is due in part to host genetic variations. Pharmacogenetic and pharmacogenomic studies have successfully identified genetic variants that contribute to this variation in susceptibility to chemotherapy. This review provides an overview of the progress made in the field of pharmacogenetics and pharmacogenomics using a five-stage architecture, which includes 1) determining the role of genetics in drug response; 2) screening and identifying genetic markers; 3) validating genetic markers; 4) clinical utility assessment; and 5) pharmacoeconomic impact. Examples are provided to illustrate the identification, validation, utility, and challenges of these pharmacogenetic and pharmacogenomic markers, with the focus on the current application of this knowledge in cancer therapy. With the advance of technology, it becomes feasible to evaluate the human genome in a relatively inexpensive and efficient manner; however, extensive pharmacogenetic research and education are urgently needed to improve the translation of pharmacogenetic concepts from bench to bedside.

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Expression of rTSβ as a 5-fluorouracil resistance marker in patients with primary breast cancer

Cited by 5 publications

References 27 publications

Enzymatic and Structural Characterization of rTSγ Provides Insights into the Function of rTSβ

Enzymatic and Structural Characterization of rTSγ Provides Insights into the Function of rTSβ

Transient knockdown and overexpression reveal a developmental role for the zebrafish enosf1b gene

Pharmacogenetics and pharmacogenomics of anticancer agents

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