Program

Provisional program of the Conference

OPENING LECTURE:

Beyond apoptosis induction: achieving tumor control by remodeling the cancer phenotype

SESSION 1

ANAKOINOSIS: CORRECTING DYSREGULATED CANCER HOMEOSTASIS FOR LONG-TERM TUMOR CONTROL

1.A. Clinical trials: Re-directing the flux of information in cancer tissue (i.e., anakoinosis)

• Hematologic neoplasia
  • Acute/chronic myelocytic leukemia
  • Myelodysplastic syndrome
  • Multiple myeloma
  • Non-Hodgkin lymphoma
• Metastatic cancer
  • Non-small cell lung cancer
  • Pediatric tumors
  • Hepatocellular carcinoma
  • Pancreatic cancer
  • Angiosarcoma

1.B. Mechanisms of metastatic tumor control: remodeling cancer phenotype beyond apoptosis

• Principles at the basis of anakoinosis effects
• Reprogramming tumor tissue
• Biologic memory
• Microenvironment and tumor fate
• Fate of cancer cells: beyond apoptosis
• Differentiation
• Trans-differentiation
• Epithelial-to-mesenchymal transition
• Changes in the microenvironment
• Anti-inflammation
• Immune evasion
• Clinical implications
• Therapy sequence: Progression-free survival 2 (PFS2)
• Overcoming poor risk parameters
• Histologically different tumors share communication lines as targets for tumor control
• Metronomic therapies: Reprogramming of cancer tissue

1.C. Anakoinosis: not only cancer

• Spread of synovial fibroblasts in rheumatoid arthritis

1.D. Reverse Anakoinosis: how carcinogenesis may arise from combination of modulators with no pro-cancerous monoactivity

• Concerted low-dose exposure to chemical mixtures

1.E. Search for systemic signature of cancer

• Hint on anakoinosis mechanisms from analysis of patients’ samples       
• Serum/plasma proteomics and lipidomics

SESSION 2

BIOLOGICAL BASIS OF ANAKOINOSIS: NORMAL AND CANCER TISSUE DYNAMICS

2.A. Communication between cell compartments in tissue

• Primary and metastatic cancer microenvironment
• Extracellular matrix
• Basement membrane
• The metastatic microenvironment
• Pre-metastatic niche
• Tissue communication and the cancer secretome
• Cross-talk between different tumor entities
• Vesicular and molecular secretory processes
• Exosome signaling
• Re-directing the flux of information in cancer microenvironment (i.e., anakoinosis)
• Dysregulated metabolism in cancer tissue
• Stress responses
• Energy production
• Authophagy
• Redox control in cancer

2.B. Not only oncogenes: epithelial control of oncogene functions

• Oncogene mutations in histologically normal tissues
• Age- and tissue-dependent oncogene mutations in non-cancer context
• Selective advantage of mutated oncogenes in non-cancer tissues
• Oncogene mutated cells in healthy tissues behave as normal cells: not enough mutations, or tight anticancer tissue controls?
• Viral carcinogenesis: when viral genes take control of cell and tissue homeostasis
• Human vs. mice viral carcinogenesis
• Viral oncogenesis can bypass cellular oncogene mutations
• Carcinogenesis and the epithelial polarity
• Role of microenvironment in control of oncogene mutated cells
• Tissue control of oncogene functions as upstream tumor suppressor barrier
• Tumor suppression by polarity genes
• LKB1 controls the oncogenic functions of Myc
• Polarity genes vs. classical tumor suppressors
• More than just oncogene-induced apoptosis and oncogene-induced senescence

2.C. Therapy-induced alteration of communication between cell compartments in tissue

• Post-therapy cancer repopulation
• COX-2 and cancer repopulation
• Genetic and micro-environment factors determining repopulation
• Epithelial-to-mesenchymal transition
• The genetic and epigenetic identity of cancer stem cells
• DNA damage response (DDR)
• Context-dependent pro- or anti-cancer role of DDR
• Senescence associated secretory phenotype and the identity of senescent cells
• Autophagy and tissue regeneration
• Endoreduplication and neosis
• Phoenix rising: when induced apoptosis projects post-therapy tissue regeneration
• Apoptosis and tissue regeneration
• Intersections between apoptotic and senescent cells secretomes
• Metronomic therapies
• Reprogramming of cancer tissue and immune response upon low pulsed dose chemotherapy
• In vitro modelling of metronomic chemotherapy
• Targeted therapy and cancer tissue remodeling

2.D. Epigenetic alterations and dysregulated homeostatic pathways and checkpoints in cancer

• Dysregulated homeostatic pathways
  • Wnt pathway in cancer
  • Notch signaling
• Modulation of transcription factors
  • STAT3 in tumor disease
• Reprogramming by epigenetic modelling
  • Regulation of tumor suppressor PTEN
  • Tumor suppressor modulation
• Regulation by non-coding RNAs

2.E. Novel technical approaches to study the principles of anakoinosis

• New prospects in animal models for studying cancer
• Real time analysis of cancer cells in mice
• Zebrafish
• High tech in vitro studies: 3D cultures
• organoids
• lab-on-chip
• Projecting in vitro the cancer microenvironment
• Co-culturing epithelial, stroma and immune infiltrates
• Microfluidic models
• Lessons from regenerative medicine
• Mathematical modelling of cancer dynamics
• Simulations of tumor cells growth and response to therapy
• Analyses in vivo

SPECIAL LECTURE: CANCER AS A TISSUE DISEASE

SESSION 3

ANAKOINOSIS, A NOVEL LONG-LASTING OPPORTUNITY FOR SUSTAINABLE DRUG DEVELOPMENT

Introduction: Anakoinosis, or targeting the functional state of tumor tissues:

why we need drug development

3.A. Developing immunotherapy

• Immunotherapy re-challenge
• Immune modelling for improving efficacy of cancer therapy
• Immunotherapeutic combination therapies

3.B. New bio-modulatory drugs

• Transcriptional modulators
• Agonists and antagonists of nuclear receptors
• Non-coding RNA
• Drug cocktail kits
• Ongoing research
• The renin angiotensin system
• MEK inhibitor, PPARγ
• Bcl2 inhibitors
• Peroxisome proliferator-activated receptor γ (PPARγ)
• Future prospective
• Drug design
• Bioinformatic approaches
• Drug repurposing: Not only saving

3.C. Stabilization of natural compounds and endogenous modulators

• Anticancer activity of natural compounds
• Pro-apoptotic activity
• Tumor microenvironment modulation
• Conjugation and encapsulation of for stabilization and targeting
• Non-coding RNA
• Nanomedicine
• Gold nanoparticles
• Drug targeting: enhanced permeability and retention effect
• Intrinsically active nanoparticles as regulators of cancer microenvironment