Changes in cobalamin metabolism are associated with the altered methionine auxotrophy of highly growth autonomous human melanoma cells

Liteplo, Robert G.; Hipwell, Sheridan E.; Rosenblatt, David S.; Sillaots, Sue; Lue-Shing, Helena

doi:10.1002/jcp.1041490222

Cited by 36 publications

(18 citation statements)

References 14 publications

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“…Each of these cofactors might be defective in tumour cells, leading to less MET synthesis. Studies have shown that some MET-dependent cell lines lack sufficient cobalamin to assure HCY methylation (Liteplo et al, 1991;Pezacka et al, 1992). MET dependency might also be a result of the low availability of HCY that would be metabolized in the transsulphuration pathway (Figure 1), which requires cystathionine j-synthase.…”

Section: Discussionmentioning

confidence: 99%

Growth of methionine-dependent human prostate cancer (PC-3) is inhibited by ethionine combined with methionine starvation

Poirson-Bichat

Gonfalone²,

Bras-Gonçalves³

et al. 1997

Br J Cancer

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Summary Methionine (MET) is required for cell metabolism. MET endogenously synthesized from homocysteine (HCY) supports the proliferation of normal cells, but not that of numerous malignant cells, as shown previously. MET starvation should have an anti-tumour effect, and its deleterious effects on the hosts might be prevented by HCY. Anti-tumour effects of MET starvation must be reinforced by ethionine (ETH), a MET analogue. MET dependency of PC-3, a human prostate cancer cell line, was studied in vitro. Proliferation of PC-3 cells, cultivated in MET-free medium, was 29% compared with growth in MET+HCY-medium. Addition of HCY to MET-free medium increased the proliferation rate to 56%. The concentration of ETH required to decrease the PC-3 cell proliferation rate to 50% (IC50) was 0.5 mg ml-1 in MET-HCY-medium. ETH-induced inhibition was abolished by MET addition and was reinforced by HCY. PC-3 cell cycle was blocked in the S-G2-phase after 30 h culture in the absence of MET; this blockage was not reversed by addition of HCY. ETH at the lC50 in MET-HCY+ medium blocked DNA replication. Apoptotic cells appeared after 30 h incubation in MET-HCY+ medium only when ETH was added. ATP pools were decreased after 15 h of culture in MET-free medium. In vivo, MET starvation was obtained by feeding tumour-bearing mice a diet containing a synthetic amino acid mixture as the protein supply, in which HCY replaced MET. Given to nude mice bearing xenografted PC-3, from day 1 after grafting and for 3 weeks, this diet inhibited tumour growth (34% on day 20, P < 0.007); this effect was potentiated by ETH (200 mg kg-' day-' i.p.) (56% on day 20, P < 5 x 1 0-5). The differences between the effects of these two treatments were significant (P < 0.017) and optimal on day 20. These data showed that combination of ETH and HCY slowed the proliferation of prostate cancer cells in vitro and in vivo, decreased ATP synthesis and caused cell cycle arrest and apoptosis. Experimental therapy based on cancer cell MET metabolism deficiency could be efficient for treating advanced prostate cancers refractory to current therapies.

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Section: Discussionmentioning

confidence: 99%

Growth of methionine-dependent human prostate cancer (PC-3) is inhibited by ethionine combined with methionine starvation

Poirson-Bichat

Gonfalone²,

Bras-Gonçalves³

et al. 1997

Br J Cancer

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“…MET-dependent tumour cells appear to synthesize MET from HCY by an active MET synthase, but at levels not adequate to both sustain growth and meet their high transmethylation requirements (Judde et al, 1989). The most likely biochemical defect leading to MET dependency is thought to be related to the synthesis and availability of methylcobalamine, which is directly involved in the transfer of methyl groups from 5-methyltetrahydrofolate to HCY (Liteplo et al, 1991;Fiskerstrand et al, 1994).…”

mentioning

confidence: 99%

Regulation of O6-methylguanine-DNA methyltransferase by methionine in human tumour cells

Kokkinakis

Wronski²,

Vuong³

et al. 1997

Br J Cancer

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Summary Methionine (MET)-dependent cell lines require MET to proliferate, and homocysteine (HCY) does not act as a substitute for this requirement. From six O6-methylguanine-DNA methyltransferase (MGMT)-efficient (mer) cell lines tested, two medulloblastomas (Daoy and D-341) and a lung non-small-cell adenocarcinoma with metastatic potential (H-1623) were most sensitive to MET deprivation, while two glioblastomas (U-138, D-263) and a small-cell lung carcinoma H-1944 were moderately to weakly dependent. Regardless of the degree of MET dependence, all of these lines down-regulated their MGMT activity within 48-72 h of transfer from MET+HCY-to MET-HCY+ media, long before the eradication of the culture. Reduction of MGMT activity was due to a decline of both MGMT mRNA and protein levels. However, the reduction was not related to the methylation status of the MGMT promoter at the Smal site or the Hpall sites in the body of the gene; such sites have been shown to be associated in MGMT regulation and in defining the mer phenotype. MET-dependent, met tumour cells cultured in MET-HCY+ were more sensitive to BCNU (IC50 = 5-1 0 gIM) than those cultured in MET+HCY-(IC50 = 45-90 gM), while MET-independent or mer cell lines were unaffected. This indicates that reduction of MGMT, imposed by the absence of MET, renders mer tumour cells more susceptible to alkylating agents. The relatively selective suppression of MGMT activity in mer MET-dependent tumour cells, in combination with the inability of such cells to proliferate in the absence of MET, may lead to the development of more effective treatment strategies for mer MET-dependent tumours.

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“…Однако на культуре клеток карциносаркомы Уокера показано, что 5-MTHF не влияет на метиониновую зависимость [83]. На примере клеток меланомы, лейкоза и глиомы GaMg дискутируется спорный ме-ханизм развития метиониновой зависимости через нарушение метаболизма кобаламина со снижением активности MTR [84][85][86]. …”

Section: механизмы развития метиониновой зависимости в опухолевых клеunclassified

Pathological Metabolism of Methionine in Malignant Cells Is a Potential Target for the Antitumor Therapy

VS¹,

Davydov²,

Anufrieva³

et al. 2017

Клиническая онкогематология

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This review presents the characteristics of the cellular metabolism of methionine, as well as known data on the mechanisms of the development of methionine dependence in malignant cells. The possibilities of using a non-methionine diet for the control of the tumor growth in patients with various forms of cancer are considered. The information about methionine Y-lyase, an enzyme providing elimination of methionine from plasma, is provided. Its role as a potential antitumor enzyme is disclosed. Data on cytotoxic activity of the enzyme, obtained from various sources, and information on tumor models and cell cultures, showing methionine dependence are summarised.

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Changes in cobalamin metabolism are associated with the altered methionine auxotrophy of highly growth autonomous human melanoma cells

Cited by 36 publications

References 14 publications

Growth of methionine-dependent human prostate cancer (PC-3) is inhibited by ethionine combined with methionine starvation

Growth of methionine-dependent human prostate cancer (PC-3) is inhibited by ethionine combined with methionine starvation

Regulation of O6-methylguanine-DNA methyltransferase by methionine in human tumour cells

Pathological Metabolism of Methionine in Malignant Cells Is a Potential Target for the Antitumor Therapy

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