Structure−Activity Relationships on Phenylalanine-Containing Inhibitors of Histone Deacetylase:  In Vitro Enzyme Inhibition, Induction of Differentiation, and Inhibition of Proliferation in Friend Leukemic Cells

Wittich, Sybille; Scherf, H. R.; Xie, Changping; Brosch, Gerald; Loidl, Peter; Gerhäuser, Clarissa; Jung, Manfred

doi:10.1021/jm0208119

Cited by 68 publications

(112 citation statements)

References 48 publications

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“…While butyrates increase fetal globin expression in many patients [2,3,[29][30][31], hematological improvement does not consistently follow fetal globin induction in β-thalassemia, suggesting that the factors described above may be blunting the clinical response. Both chemotherapeutic agents and histone deacetylase inhibitors, such as butyrates, inhibit cell proliferation through induction of the cyclindependent kinase inhibitors p21 Cip and p27 Kip , with resulting cell cycle arrest, and are known to induce irreversible arrest or apoptosis in cancer cells [13][14][15][16]. Although normal cells can recover from this butyrate-induced growth arrest, β-thalassemia erythroid cells may be impaired in their ability to recover, due to the additional cellular stresses they endure.…”

Section: Discussionmentioning

confidence: 99%

“…This accelerated apoptosis may be aggravated by the cellular growth arrest induced by some of these fetal globin-inducing agents. For example, some histone deacetylase inhibitors, such as the butyrates, are known to inhibit cell proliferation, through arrest in the G 1 phase of the cell cycle, resulting in irreversible apoptosis in certain cell types [13][14][15][16]. We previously hypothesized that inhibition of cell proliferation by arginine butyrate and sodium phenylbutyrate may augment the accelerated erythroid apoptosis characteristic of β-thalassemia, and therefore sought to identify alternative HbF-inducing agents which were not growth-inhibitory.…”

Section: Introductionmentioning

confidence: 99%

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Enhancement of growth and survival and alterations in Bcl-family proteins in β-thalassemic erythroid progenitors by novel short-chain fatty acid derivatives

Castañeda

Boosalis

Emery

et al. 2005

Blood Cells, Molecules, and Diseases

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Accelerated apoptosis of erythroid progenitors is a characteristic of β-thalassemia which presents a significant barrier to definitive therapeutic approaches utilizing induction of endogenous fetal globin gene expression. γ-globin gene expression may not be inducible in, or may not be able to rescue, erythroid cells in which programmed cell death is initiated early in erythroblast development. In this report, short-chain fatty acid derivatives (SCFADs) which induce fetal globin gene expression were tested for their ability to promote proliferation and survival of erythroid progenitors cultured from β-thalassemic subjects, and of cytokine-dependent erythroid cell lines. Certain SCFADs promoted thalassemic Bfu-e growth and cytokine-independent growth and survival of erythroid cell lines. A 40-80% increase in erythroid Bfu-e colony number was observed in cultures established with any of five mitogenic SCFADs, compared to control or butyrate-treated cultures from the same subjects. Immunoblot analysis demonstrated that these same SCFADs also regulated the expression of specific protein inhibitors of apoptosis. Antiapoptotic ratios of the proteins Bcl-x L /Bcl-x S in thalassemic Bfu-e were increased by 30-120% with exposure to the SCFDs, compared to the ratios in the same cells cultured under control conditions. Similar anti-apoptotic increases in Mcl-1 L /Mcl-1 S ratios were induced by the SCFADs. These findings suggest that select fetal globin-inducing SCFADs which enhance proliferation of β-thalassemia progenitors may enhance survival of these progenitors by altering levels of Bcl-family protein members. This combination of effects should enhance erythroid cell survival in the β-thalassemia syndromes, allowing fetal globin gene expression to be induced more effectively than currently available, growth-suppressing, fetal globin-inducing agents, such as the butyrates or chemotherapeutic agents.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Enhancement of growth and survival and alterations in Bcl-family proteins in β-thalassemic erythroid progenitors by novel short-chain fatty acid derivatives

Castañeda

Boosalis

Emery

et al. 2005

Blood Cells, Molecules, and Diseases

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“…Reduction of the nitro group was achieved by Pd (OH) 2 catalyzed hydrogenation or in case of the tyrosine intermediate 3e, by using tin (II) chloride to avoid undesirable O-benzyl group cleavage. The resulting biphenylamines 4a-e were coupled with 7-benzyloxycarbamoylheptanoic acid (5) [24] by PyBOP to afford the corresponding amides 6a-e. Acid deprotection of the BOC group followed by hydrogenation led to the hydroxamates 7a-e.…”

Section: Chemical Synthesismentioning

confidence: 99%

Chemistry, Biology, and QSAR Studies of Substituted Biaryl Hydroxamates and Mercaptoacetamides as HDAC Inhibitors—Nanomolar‐Potency Inhibitors of Pancreatic Cancer Cell Growth

et al. 2008

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The histone deacetylases (HDACs) are able to regulate gene expression and inhibitors of the HDACs (HDACIs) hold promise in the treatment of cancer as well as a variety of neurodegenerative diseases. To investigate the possibility to achieve some measure of isoform selectivity in the inhibition of the HDACs, we prepared a small series of 2,4′-diaminobiphenyl ligands functionalized at the para-amino group with an appendage containing either a hydroxamate or a mercaptoacetamide group and coupled to an amino acid residue at the ortho-amino group. A smaller series of substituted phenylthiazoles was also explored. Some of these newly synthesized ligands show low nM potency in the HDAC inhibition assays and display micromolar to low nanomolar IC 50 values when tested against five pancreatic cancer cell lines. The isoform selectivity of these ligands for the Class I HDACs (HDAC1-3 and 8) and Class IIb HDACs (HDAC6 and HDAC10) together with QSAR studies of their correlation with the lipophilicity are presented. Of particular interest is the HDAC6 selectivity of the mercaptoacetamides.

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“…For example, acetylation of p53 results in stabilization of the protein and increased DNA binding and transactivation. [22][23][24][25][26][27][28] Inhibition of HDAC6 causes acetylation of HSP90 leading to proteosomal degradation of its client proteins such as the ErbB2 oncoprotein. [22][23][24] …”

Section: Transcription and Histone Deacetylases (Hdacs)mentioning

confidence: 99%

“…The cap structure of HDACI interacts with amino acids at the entrance rim of the N-acetyl lysine binding channel of the HDAC, which determines the specificity of the inhibitor. 26 According to their chemical nature and mechanism of inhibition, HDACIs are classified into the following groups: short-chain fatty acids, epoxides, cyclic peptides, hydroxamic acids, benzamides, and other hybrid compounds. [3][4][5][6][7][8][9][27][28][29][37][38][39] In general, compared with inhibitors used in earlier studies, the newer agents are effective at nanomolar concentrations and are also less toxic.…”

Section: Histone Deacetylase Inhibitors (Hdacis)mentioning

confidence: 99%

Histone Deacetylase Inhibitors for Cancer Therapy

Kim¹,

Bang²,

Robertson³

2006

Epigenetics

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The epigenome of cancer cells is determined by DNA methylation and an array of post-translational modifications of the core histones. Epigenetic abnormalities are commonly found in human tumors and importantly, they can be reversed by pharmacologic inhibitors. Histone deacetylase inhibitors (HDACIs) represent one of the most promising epigenetic treatments for cancer. HDACIs have emerged as promising targets for cancer therapy because they reactivate the transcription of multiple genes that are silenced in human tumors and they show pleiotropic anti-tumor effects selectively in cancer cells. HDACIs are well-tolerated and several show promising anti-tumor activity. While gene transcription has been considered to be the major target of HDACIs, inhibition of acetylation of non-histone proteins is now emerging as a novel basis for their anti-tumor effects. In this review, we discuss new insights into the molecular mechanism of HDACIs, their current status of clinical development, and possible future uses in cancer therapy.

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Structure−Activity Relationships on Phenylalanine-Containing Inhibitors of Histone Deacetylase: In Vitro Enzyme Inhibition, Induction of Differentiation, and Inhibition of Proliferation in Friend Leukemic Cells

Cited by 68 publications

References 48 publications

Enhancement of growth and survival and alterations in Bcl-family proteins in β-thalassemic erythroid progenitors by novel short-chain fatty acid derivatives

Enhancement of growth and survival and alterations in Bcl-family proteins in β-thalassemic erythroid progenitors by novel short-chain fatty acid derivatives

Chemistry, Biology, and QSAR Studies of Substituted Biaryl Hydroxamates and Mercaptoacetamides as HDAC Inhibitors—Nanomolar‐Potency Inhibitors of Pancreatic Cancer Cell Growth

Histone Deacetylase Inhibitors for Cancer Therapy

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