Literature DB >> 20038269

Osteoblastogenesis and tumor growth in myeloma.

Shmuel Yaccoby1.   

Abstract

Myeloma is associated with suppression of osteoblastogenesis, consequentially resulting in increased osteoclast activity and induction of typical osteolytic bone disease. The molecular mechanisms by which myeloma cells suppress osteoblastogenesis and the consequences of increased osteoblast activity on myeloma cell growth have been partially delineated only recently. Reduced osteoblastogenesis is a consequence of abnormal properties and impaired osteogenic potential of osteoprogenitor cells from myeloma patients and is also the result of production of multiple osteoblastogenesis inhibitors by myeloma cells and by microenvironmental cells within the myelomatous bone. Nevertheless, novel osteoblast-activating agents (e.g. proteasome inhibitor bortezomib) are capable of inducing bone formation in myeloma animal models and clinically. These agents induce increased osteoblast activity, often coupled with a concomitant reduction in osteoclastogenesis, that is strongly associated with reduced myeloma tumor burden. In vitro, osteoblasts, in contrast to osteoclasts, attenuate the growth of myeloma cells from a large subset of patients; potential molecular mechanisms are discussed. These studies suggest that myeloma cells suppress osteoblastogenesis to their advantage and that increased osteoblast activity is a promising approach to treat myeloma bone disease and simultaneously control myeloma development and progression.

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Year:  2010        PMID: 20038269      PMCID: PMC2849287          DOI: 10.3109/10428190903503438

Source DB:  PubMed          Journal:  Leuk Lymphoma        ISSN: 1026-8022


  83 in total

Review 1.  Mechanisms of bone metastasis.

Authors:  G David Roodman
Journal:  N Engl J Med       Date:  2004-04-15       Impact factor: 91.245

2.  The ephrinB2/EphB4 axis is dysregulated in osteoprogenitors from myeloma patients and its activation affects myeloma bone disease and tumor growth.

Authors:  Angela Pennisi; Wen Ling; Xin Li; Sharmin Khan; John D Shaughnessy; Bart Barlogie; Shmuel Yaccoby
Journal:  Blood       Date:  2009-07-13       Impact factor: 22.113

3.  Mesenchymal stem cells from multiple myeloma patients display distinct genomic profile as compared with those from normal donors.

Authors:  M Garayoa; J L Garcia; C Santamaria; A Garcia-Gomez; J F Blanco; A Pandiella; J M Hernández; F M Sanchez-Guijo; M-C del Cañizo; N C Gutiérrez; J F San Miguel
Journal:  Leukemia       Date:  2009-04-09       Impact factor: 11.528

Review 4.  Growth factor control of bone mass.

Authors:  Ernesto Canalis
Journal:  J Cell Biochem       Date:  2009-11-01       Impact factor: 4.429

5.  Aurora kinase A is a target of Wnt/beta-catenin involved in multiple myeloma disease progression.

Authors:  Jui Dutta-Simmons; Yunyu Zhang; Gullu Gorgun; Moshe Gatt; Mala Mani; Teru Hideshima; Kohichi Takada; Nicole E Carlson; Daniel E Carrasco; Yu-Tzu Tai; Noopur Raje; Anthony G Letai; Kenneth C Anderson; Daniel R Carrasco
Journal:  Blood       Date:  2009-08-03       Impact factor: 22.113

6.  Illegitimate WNT signaling promotes proliferation of multiple myeloma cells.

Authors:  Patrick W B Derksen; Esther Tjin; Helen P Meijer; Melanie D Klok; Harold D MacGillavry; Marinus H J van Oers; Henk M Lokhorst; Andries C Bloem; Hans Clevers; Roel Nusse; Ronald van der Neut; Marcel Spaargaren; Steven T Pals
Journal:  Proc Natl Acad Sci U S A       Date:  2004-04-05       Impact factor: 11.205

7.  Cancer and the microenvironment: myeloma-osteoclast interactions as a model.

Authors:  Shmuel Yaccoby; Michele J Wezeman; Aminah Henderson; Michele Cottler-Fox; Qing Yi; Bart Barlogie; Joshua Epstein
Journal:  Cancer Res       Date:  2004-03-15       Impact factor: 12.701

8.  IL-3 expression by myeloma cells increases both osteoclast formation and growth of myeloma cells.

Authors:  Jun Won Lee; Ho Yeon Chung; Lori A Ehrlich; Diane F Jelinek; Natalie S Callander; G David Roodman; Sun Jin Choi
Journal:  Blood       Date:  2003-11-13       Impact factor: 22.113

9.  The role of the Wnt-signaling antagonist DKK1 in the development of osteolytic lesions in multiple myeloma.

Authors:  Erming Tian; Fenghuang Zhan; Ronald Walker; Erik Rasmussen; Yupo Ma; Bart Barlogie; John D Shaughnessy
Journal:  N Engl J Med       Date:  2003-12-25       Impact factor: 91.245

10.  Proteasomal degradation of Runx2 shortens parathyroid hormone-induced anti-apoptotic signaling in osteoblasts. A putative explanation for why intermittent administration is needed for bone anabolism.

Authors:  Teresita Bellido; A Afshan Ali; Lilian I Plotkin; Qiang Fu; Igor Gubrij; Paula K Roberson; Robert S Weinstein; Charles A O'Brien; Stavros C Manolagas; Robert L Jilka
Journal:  J Biol Chem       Date:  2003-10-01       Impact factor: 5.157
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  27 in total

1.  Mesenchymal stem cells gene signature in high-risk myeloma bone marrow linked to suppression of distinct IGFBP2-expressing small adipocytes.

Authors:  Syed J Mehdi; Sarah K Johnson; Joshua Epstein; Maurizio Zangari; Pingping Qu; Antje Hoering; Frits van Rhee; Carolina Schinke; Sharmilan Thanendrarajan; Bart Barlogie; Faith E Davies; Gareth J Morgan; Shmuel Yaccoby
Journal:  Br J Haematol       Date:  2018-11-08       Impact factor: 6.998

Review 2.  Dynamic interplay between bone and multiple myeloma: emerging roles of the osteoblast.

Authors:  Michaela R Reagan; Lucy Liaw; Clifford J Rosen; Irene M Ghobrial
Journal:  Bone       Date:  2015-02-26       Impact factor: 4.398

Review 3.  TRAF6 activation in multiple myeloma: a potential therapeutic target.

Authors:  Hong Liu; Samantha Tamashiro; Stavroula Baritaki; Manuel Penichet; Youhua Yu; Haiming Chen; James Berenson; Benjamin Bonavida
Journal:  Clin Lymphoma Myeloma Leuk       Date:  2012-03-21

4.  Mesenchymal stem cells expressing osteoprotegerin variants inhibit osteolysis in a murine model of multiple myeloma.

Authors:  Jerome T Higgs; Joo Hyoung Lee; Hong Wang; Vishnu C Ramani; Diptiman Chanda; Cherlene Y Hardy; Ralph D Sanderson; Selvarangan Ponnazhagan
Journal:  Blood Adv       Date:  2017-11-21

Review 5.  Bone disease from monoclonal gammopathy of undetermined significance to multiple myeloma: pathogenesis, interventions, and future opportunities.

Authors:  Alex R Minter; Haley Simpson; Brendan M Weiss; Ola Landgren
Journal:  Semin Hematol       Date:  2011-01       Impact factor: 3.851

Review 6.  Bone disease in multiple myeloma and precursor disease: novel diagnostic approaches and implications on clinical management.

Authors:  Sigurdur Y Kristinsson; Alex R Minter; Neha Korde; Esther Tan; Ola Landgren
Journal:  Expert Rev Mol Diagn       Date:  2011-07       Impact factor: 5.225

7.  Thymidine phosphorylase exerts complex effects on bone resorption and formation in myeloma.

Authors:  Huan Liu; Zhiqiang Liu; Juan Du; Jin He; Pei Lin; Behrang Amini; Michael W Starbuck; Nora Novane; Jatin J Shah; Richard E Davis; Jian Hou; Robert F Gagel; Jing Yang
Journal:  Sci Transl Med       Date:  2016-08-24       Impact factor: 17.956

Review 8.  Adipose, Bone, and Myeloma: Contributions from the Microenvironment.

Authors:  Michelle M McDonald; Heather Fairfield; Carolyne Falank; Michaela R Reagan
Journal:  Calcif Tissue Int       Date:  2016-06-24       Impact factor: 4.333

9.  Activating transcription factor 4, an ER stress mediator, is required for, but excessive ER stress suppresses osteoblastogenesis by bortezomib.

Authors:  Shingen Nakamura; Hirokazu Miki; Shinsuke Kido; Ayako Nakano; Masahiro Hiasa; Asuka Oda; Hiroe Amou; Keiichiro Watanabe; Takeshi Harada; Shiro Fujii; Kyoko Takeuchi; Kumiko Kagawa; Shuji Ozaki; Toshio Matsumoto; Masahiro Abe
Journal:  Int J Hematol       Date:  2013-05-25       Impact factor: 2.490

Review 10.  Targeting Intrinsic and Extrinsic Vulnerabilities for the Treatment of Multiple Myeloma.

Authors:  Nagaraju Anreddy; Lori A Hazlehurst
Journal:  J Cell Biochem       Date:  2016-06-21       Impact factor: 4.429
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