NCT Conference, Heidelberg, Germany, September 24, 2013 · NCT Conference, Heidelberg, Germany,...

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Roche Penzberg: A fully integrated Oncology R & D site with all key functions NCT Conference, Heidelberg, Germany, September 24, 2013 Manipulation of the Tumor Micro Environment by Depletion of Tumor Associated Macrophages Klaus Bosslet, Head Discovery Oncology Penzberg, Pharma Research and early Development (pRED), Roche Diagnostics GmbH; Roche Penzberg, 30 km South of Munich and 25 km North of Garmisch. (A 6 minutes drive with your 911) With 5000 employees probably the largest R+D site in Europe

Transcript of NCT Conference, Heidelberg, Germany, September 24, 2013 · NCT Conference, Heidelberg, Germany,...

Roche Penzberg: A fully integrated

Oncology R & D site with all key functions

NCT Conference, Heidelberg, Germany, September 24, 2013

Manipulation of the Tumor Micro Environment by Depletion of Tumor

Associated Macrophages Klaus Bosslet, Head Discovery Oncology Penzberg, Pharma Research and early Development (pRED),

Roche Diagnostics GmbH;

Roche Penzberg,

30 km South of

Munich and 25 km

North of Garmisch.

(A 6 minutes drive

with your 911)

With 5000

employees probably

the largest R+D

site in Europe

Vision – where the science is driving us

Understand patients and their disease to achieve CURE

Cancer cell-directed targets • Signalling inhibition

(e.g. ALK; HER3)

• Apoptosis induction

(e.g. targeted IT)

• Tumor Suppression

(e.g. MDM2)

+ +

Dysregulated

cell signaling

Tumor-Micro-

Environment

(TME)

Cancer

Immunotherapy

Individually necessary but not sufficient. CURE requires a multi-paradigm approach.

Engage host immune response via

Systemic modulation of immunity

Tumor targeted immune modulation • Glyco-enhanced Abs

• Cytokine Ab fusions

• T-cell bispecific Abs

Modulate immuno

suppressive TME • Elimination and switching of

M2 macrophages

(e.g. CSF1R Mab, AICs)

• Anti-Angiogenesis

(e.g. Ang2/VEGF Mab)

2 Confidential information – do not copy or distribute

Modulation of the Tumor Micro Environment

Treatment Barriers in Tumor Micro Environment

Tumor heterogeneity: Molecular and cellular heterogeneity of tumor cell population => limits efficacy of targeted signal transducing and apoptosis inducing drugs

Cancer initiating cells: A quiescent cell within the tumor micro environment with the potential to generate a new tumor being vastly resistant towards anti proliferative drug therapy

Tumor supportive ECM: Connective tissue and CAFs generate a pro-tumorigenic milieu, produce growth factors contributing to resistance towards targeted drugs

Aberrant vascular network: Limits accessibility for both low molecular as well as high molecular weight drugs

Immuno suppressive phenotype: Accumulation of anergic immune and inflammatory cells within the tumor mass (T-reg and M2 M accumulation) => T-cells activated by peripheral immunisation show limited efficacy in the established tumor micro environment

Cancer drugs with „step change potential“

have to overcome these Treatment Barriers

Mikala Egeblad,1,*

Elizabeth S.

Nakasone, 1,2

and Zena Werb3,*

Evolutionary Neo-Organ

Tumors escape host immune response by inducing an

immuno- suppressive Tumor Microenvironment (iTME) by

recruitment of myeloid cells

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Immune Suppression

Tumor Immunity

TAM e.g.

M2c-M

MDSC

DC Treg

IL-10, TGF-β, CCL-2 …

CTL

Th

B

NK

IL-2, IFN-γ …

Target myeloid cells

- First in class opportunity

- Tumor specific

- Low risk for autoimmunity

Strategy:

Enable effective anti-tumor immune

response by targeting key

immunosuppressive myeloid cells

CSF-1R as Survival and Differentiation Factor for TAMs Tumor associated macrophages are alternatively activated M2 -Mφ

Tumor-eliminating

adapted from Pollard Nat Rev. Immunol. 2009

Survival

Differentiation

engaging Mabs

Depletion of M2-Mφ by anti-CSF-1R therapy offers opportunity

to inhibit various signaling and effector molecules at the same time

to target genetically stable cells in contrast to genetically instable tumor cells

M2-Mφ can be discriminated from M1-Mφ by differential expression of scavenger receptor CD163

M1

CD

68

Monocyte

Inflammatory

macrophage (M1)

Tumor-promoting

huMab CSF-1R

RG7155

M2

CD

68

Alternatively activated

macrophage (M2)

Colony-Stimulating Factor-1 Receptor structure Binding of CSF-1 or IL-34 induce homodimerization

6 Adapted from Hamilton J Nature Rev Immunol . 2008; 8(7):533-544

CSF-1R

CSF-1/

IL-34

RG7155, a novel humanized FIC anti-CSF-1R mAb Highly potent, specific and purely antagonistic CSF-1R inhibitor

Data: Kaluza, Scheiblich, Lanzendörfer, Fertig/Runza and Dimoudis labs,

Crystal structure: J. Benz and I. Gorr and team pRED Basel and Penzberg

Light chain

ligand binding

(D1-D3)

dim

eri

zation

in

terf

ace

(

D4 a

nd

D5)

RG7155*

Fab Fragment

* Chimeric antibody variant

Isotype: IgG1

Binding to domain in CSF-1R ECD: domain

D4/D5

Affinity to human CSF-1R (Biacore): <1nM

Affinity to Cynomolgus CSF-1R (Biacore): <1nM

Inhibition of pCSF-1R*: <2 nM

Inhibition of CSF-1/CSF-1R complex formation IC50:* <1 nM

Monocyte survival assay IC50: <1 nM

Osteoclast differentiation assay IC50: <3 nM

Activation of monocytes: none

NIH3T3 CSF-1R (L301S,Y969F) viability IC50: <100nM

Summary of key data for RG7155

Heavy chain

RG7155 targets essential Mφ pathway

RG7155 induces cell death of M2-like CSF-1R+CD163+ Mφ

8 Data: Valeria Runza lab pRED Penzberg *adapted from J. Pollard Nat Rev Immunol. 2009; 9(4):259-270

M1

% o

f all c

ells

p-value 0.11

p-value 0.02 *

Monocyte

CSF-1R+CD163+ Mφ

CSF-1R-CD80+ Mφ

CSF-1

GM-CSF

M2

*

Anti–CSF-1R mAb in transgenic BC model Targeting mouse CSF-1R enhances efficacy of chemotherapy

10 Karin deVisser lab Netherlands Cancer Institute, Amsterdam

Oral Presentation Metamia Ciampricotti, Keystone Symposium Dublin 2012

p=0.001

anti-CSF-1R + Cisplatin

Control ab

Control ab + Cisplatin

anti-CSF-1R

0 10 20 30 40 50 60 70

0

20

40

60

80

100

Days after initiation of treatment

% s

urv

ival

Acknowledgement:

Carola Ries, rPL

Michael Cannarile, BML

Dominik Rüttinger, TML

and the many other colleagues of the CSF1R

project team

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