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Mechanisms of Immune Evasion by Tumors

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Title: Mechanisms of Immune Evasion by Tumors


1
Mechanisms of Immune Evasion by Tumors
  • W.H. Chambers, Ph.D.
  • Associate Director for Basic Research
  • University of Pittsburgh Cancer Institute
  • Associate Professor of Pathology
  • University of Pittsburgh School of Medicine

2
DCs migrate to Secondary Lymphoid Organs To
Stimulate Immunity
Tumor specific T cells migrate into tumors And
mediate specific anti-tumor functions
3
Innate capacity of lysis
LGL
CD3-, CD16, CD56, CD158, CD161
NK- more HSV, more tumors
NK IT better prognosis
4
NK Infiltration at Tumor SiteCorrelates with
Improved Prognosis
  • Hepatocellular carcinoma (Taketomi 1998) plt.0001
  • Adenocarcinoma Lung (Takanami 2001) plt.0002
  • Laryngeal carcinoma (Gonzalez 1998)
  • ? Cirrhosis (Kawarabayashi 2000)
  • Leukemia (Lowdell 2002)
  • Gastric carcinoma (Ishigami 2000) plt.01
  • Colorectal carcinoma (Coca 1997) plt.001
  • Gastric carcinoma (Takeuchi 2001) plt.05
  • Squamous Cell Lung (Villegas 2002) p.03
  • Uterine Cervix (Vaquer 1990)

5
Stellate Morphology
Most Efficient APCs
CD80, CD86, CD83, Class I/II, CD205, CD209
pDC, lyDCs, myDCs
Promote Th1 DC1 or Th2 DC2
Produce IL12, IL2
DC IT better prognosis
6
Figure 8. Day 9 bone marrow
derived cultures are enriched for mature DCs.
FACS analyses for the indicated
cell surface markers was performed on day 8 of
cultures generated with GM-CSF,
IL4 and FL (top panels), and on day 9 after 18-24
hrs of subculture in the
absence of FL (bottom panels). Shaded area,
specific Ab staining. Light area, isotype control
Ab staining.
7
DC Infiltration at Tumor SitesCorrelates with
Improved Prognosis
  • Basal Cell (Bergefelt 1992,1994)
  • Melanoma (Toriyama 1993)
  • Cervical (Nakono 1992,1993)
  • Esophogeal (Furihata 1992)
  • Gastric (Tsujitani 1992,1993,1995)
  • Hodgkins (Alavaikko 1994)
  • Lung (Zeid 1993)
  • Tongue (Goldman and Lotze 1998)
  • Pancreas (Dallal and Lotze 2002)
  • HN (Whiteside and Storkus 2002)

8
Gliomas Incidence and Prognosis
  • Most commonly diagnosed primary brain tumor
  • Include astrocytomas (gt90 of gliomas),
    oligodendrogliomas, and ependymomas
  • 15-17,000 new cases/yr in the US
  • 15-17,000 deaths/yr in the US
  • Brain and CNS tumors 3rd leading cause of
    cancer-related deaths in US males (15-34 yr) 4th
    leading cause of cancer-related deaths in US
    females (15-34 yr)
  • Median survival (conventional therapy) for high
    grade gliomas is 10-12 months

9
The Nature and Anatomic Location of Gliomas
Limits Conventional Approaches to Therapy
  • Surgery complete resection cannot be
    accomplished because of diffuse infiltratation
    into surrounding tissue and because of the need
    to preserve neurologic function
  • Chemotherapy affected to some extent by
    blood-brain-barrier, drug resistance, and by
    neurotoxic effects of drugs
  • Radiotherapy targeting difficult because of the
    infiltrative nature of gliomas, their relative
    radiation insensitivity, and the delayed
    radiation necrotic effects of doses sufficient to
    kill tumor cells

10
The location and biology of gliomas limits the
efficacy of conventional therapies
11

Gliomas Have a Number of Mechanisms for
Suppression or Evasion of the Immune System
  • Production of soluble suppressive factors - TGFb,
    IL10, sFHL
  • Disruption of antigen presentation TAP
    deficiency, b2-M deficiency, Class I deficiency
    (some or all)
  • Elimination of effector cells CD95L
  • Protection from lytic mechanisms sCD95, CD36,
    CD46, CD55, CD59

12
9L Tumors Are Infiltrated by NK Cells, But There
Are Some Surprises!
NK Cells
NK/T Cells
T Cells
13
Confocal Analyses Confirming Relative
Infiltration of 9L Glioma by CD161bright and
CD161dim Lymphocytes
14
Table 1. Comparison of Lytic Activity of CD161
Cells Isolated from Normal Splenocytes vs
Established (Day 14) 9L Gliosarcoma
CD161bright CD161dim Normal
Spleen 9L-Derived Normal Spleen 9L-Derived Exp.
1 501 697.4 414.1 60.8
13.0 251 603.6 ND
50.6 10.5 12.51 502.8
ND 32.9 31.3 6.251
335.4 ND 50.7
31.5 Exp. 2 501 92 9.8 ND
303.8 226.9 251 8112.4
344.5 212.4 172.8 12.51 72
6.8 295.2 140.6 110.5 6.251
3310.7 243.0 116.5 113.5
LU30/106 206 32 12
8 ET ratio Percent specific
cytotoxicity in 51Cr release assay
15
Elimination or reversal of the effects of TGFb
has been embraced as a means of enhancing
immunity to gliomas
  • Constitutive expression of TGFb anti-sense
    results in reduced tumorigenicity
  • Constitutive expression of TGFb anti-sense
    results in enhanced immunogenicity
  • Treatment with TGFb anti-sense oligos results in
    reduced tumorigenicity
  • Unfortunately, clinical application has not
    proven effective

16
Receptors for TGFb
  • Heteromeric complex
  • Type I - 53 kDa (2 isoforms)
  • Type II - 75 kDa (2 isoforms)
  • Type III - 300 kDa (beta-glycan)
  • Type II has serine-threonine kinase activity
  • Receptors are expressed ubiquitously

17
NK
Tu
NK
18
9L-TGFbsr is more susceptible to NK cell-mediated
lysis than 9L-neo
19
9L-TGFbsr is less tumorigenic than 9L
20
9L-neo NK depletion
9L-TGFßsr NK depletion
9L-neo
9LTGFbsr
Tumor size cm3




Days After Implantation








b
sr Mediated
Figure 7. Depletion of CD161
Cells Results in Reversal of the TGF
Loss of Tumorigenicity.
Rats were given either 9L-neo or 9L-TGF
b
sr coupled with
either mAb 3.2.3 or an isotype control mAb.
Tumor size was determined at various
intervals using calipers. P lt0.05.
21
Enhanced Survival of Rats with IC 9L-TGFbsr vs
9L-neo
120
100
80
9L-NEO
Percent Survival
60
9L-TGFBsr
40
20
0
0
5
10
15
20
25
30
35
Days After Tumor Implantation
22
What can we conclude from these experiments?
  • Local expression of TGFbsr reduces tumorigenicity
  • CD161 cells are important in the anti-tumor
    effects in vivo, and their activity is regulated
    by TGFb
  • Some increase 22-40 in survival is associated
    with local expression of TGFbsr

23
DCs migrate to Secondary Lymphoid Organs To
Stimulate Immunity
24
Intra-tumoral Delivery of iDCs into Intracranial
9L Does Not Enhance Survival
Yang et al., Cancer Res. 622583, 2002
25
MHC Class II Cells Undergoing Apoptosis in 9L
Tumors
26
  Table 4. Apoptosis of OX62 Dendritic Cells in
9L Tumors   Total Cells OX62
Cells OX62/VAD-FMK Apoptotic Cells  
608a 39 11
28.0 627 55 10
18.0 666 47
4 8.5 666 66
3 4.5 635 32
5 15.6 818 36
4 11.1 564
30 11 36.7 695
12 5 41.6  
4015.5 2112.7 aTotal
cells tabulated using Hoescht staining of intact
nuclei.
27
What Receptor Ligand Interactions Are
Responsible for Induction of Apoptosis of DC?
  • Soluble Factor Produced by Tumor Cells?
  • Tumor Cell Surface Receptor?
  • Extracellular Matrix Proteins?
  • Combination of Factors?

28
Ethidium bromide stained RT-PCR products using
iNOS specific primers
Southern blotting of iNOS RT-PCR products
Western blot using iNOS specific mAb
29
Induction of Apoptosis by HA of DC
TUNEL Assay and FITC-VAD-FMK
30
Induction of DC Apoptosis is Based Upon CD44HA
Interactions
31
What can we conclude from these experiments?
  • Intra-tumoral delivery of DC did not increase
    survival of 9L bearing rats even when RS was used
    to induce tumor apoptosis
  • DC in 9L undergo apoptosis as a consequence of
    iNOS production induced via CD44HA interactions
  • Local expression of IL12 decreases DC apoptosis
    in 9L

32
Co-culture of NK Cells and DCs Results in Their
Reciprocal Activation Which Induces Enhanced
Anti-tumor Lytic Function
Tu
Fernandez et al. Nature Medicine 5405-411
(1999). Ferlazzo G. et al, J. Exp. Med.
195343-51, 2002. Piccioli D. et al, J. Exp.
Med. 195335-41, 2002. Gerosa F. et al, J. Exp.
Med. 195327-33, 2002
33
Co-incubation of NK Cells and iDC Results in
Enhanced Tumor Cell Lysis



34
Co-incubation of NK Cells and DC Does Not Result
in Enhance Lysis of 9L Gliosarcoma

Additionally IL4 has no effect Anti-Class I has
no effect
Anti-Class I - IL4 -
35
Based on these data, we are posing three
questions1) What NKDC receptorligand
interactions promote enhanced tumor cell
lysis?2) Are those interactions important for
promoting non-adaptive and adaptive immunity?3)
Are expression and function of those receptors
and ligands affected locally and/or systemically
by the immunosuppressive effects of tumors?
36
Potential receptorligand interactions regulating
NKDC reciprocal activation?
  • NK Cell DC
  • CD2 CD58
  • CD11a CD50/CD54/CD102
  • CD11b/CD18 CD54
  • CD47 CD172
  • CD56 CD171
  • TNFfl TNFfr CD120a, -b
  • CD158 MHC Class I
  • CD159/CD94 MHC Class I
  • CD161b,d/f Clrb/g
  • Ly49 MHC Class I
  • NKp30 ?

37
Activation and inhibition receptors on NK cells
that bind Ligands on DCs Do they play a role
in inducing cytotoxicity?


NK

DC
Tumor


Charged residue in the TM region for docking
of adaptor proteins with ITAM
ITIM I/VXYXXL
38
Activation and inhibition receptors on NK cells
that bind Ligands on DCs Do they play a role
in inducing cytotoxicity?


Clrg
CD161F
?
NK
NKp30
DC
Tumor
Clrb
CD161A
CD161B,D


Charged residue in the TM region for docking
of adaptor proteins with ITAM
ITIM I/VXYXXL
39
Are CD161-Clr Interactions Involved in the
Enhanced Tumor Cell Lysis Induced NKDC
Co-culture?
  • Strategy RNA interference
  • siRNA design Dharmacon siDesign Center

  • Motifs 5-AA(N19)UU


  • 5-AA(N21)

  • 5NA(N21)
  • Transfection method Oligofectamine

  • Nucleofection
  • Detection Flow cytometry


  • Northern blot/Realtime PCR

  • Cytotoxicity Assays

40
5-AA(N19)UU Motifs for Primers for siRNA
for CD161s, Clrb and
NKp30   Receptors Targeted Sequence Location G/C
Content   CD161A
AAGCACGTGTCTACCTCAGTT
26-44 53 CD161A
AAGACTGCCGCGGGGGCTCAG 56-76 71  
CD161B AAGTGGTCTATGCGGACTTAC
199-217
53 CD161B AAGCGCGAGCCACCTCCATCT
(Invitrogen) 241-261 62 CD161A -B
AAAACAGGTAGTCCAGCTAAG
269-289 43 CD161A -B
AAGGAGCCACGTTGCTGCTCG 560-582
56 CD161A -B AAGTGGATAAACGGCTCGACT
682-704 43 CD161F
AAAGAGTCTATGGTAATGTAA
13-31 31 CD161F
AATGCTTAATTATTTCTCAAA 311-333 17 CD161F
AAGAAGCCACTTTGTTGATCA 374-396
35 CD161F AAAATGAAGAAGAACTGAAGT
398-420 26 CD161F
AACTGAAGTTTGTGCAGAACA 410-432 35 CD161F
AAAGGGAAGACAGCAGTTATT 435-457
35 CD161F AAGTGGATAAATGGCTCTGTT
496-518 35 Clrb/Ocil
AACTGCTGCTACGTAGTGATC
411-429 53 Clrb/Ocil
AACCATAAATACTTATGCTGC 498-520
30 Clrb/Ocil AAGGGGCCGAGCTAGCACGAT
614-636 56 Clrb/Ocil
AAAGGGAGTTCAGGTTACTGG 673-695 43 NKp30
AAGGTGCTGTTGATCGTCTTC
312-330 53
NKp30 AAGGACATCCAAAGCCATGAC
591-609 53 NKp30
AACCGGCAGTGTCATCTATTA 794-812 47 (3 ml
Oligof. 12 ml Opti-MEM) (3 ul 20 mM siRNA
50 ml Opti-MEM) 32 ml Opti-MEM Added to 500 ml
cells in CM

41
Targeted siRNA Treatment of DCs Results in
Reduced Message for Clrb Realtime PCR
42
Clrg
CD161F
?
NK
DC
Tumor
Clrb
CD161A
CD161B,D
43
Reduction in Expression of CD161B in A-NK Cells
Using siRNA Oligonucleotides
Control
Control
siRNA Control
siRNA CD161B
Cell No.
Mean Fluorescence Intensity
44
What can we conclude from these experiments?
  • siRNA targeting of Clrb in DCs verified by
    Realtime PCR
  • siRNA targeting of Clrb in DCs results in reduced
    enhancement of lytic activity against YAC-1
    following A-NKDC co-culture
  • siRNA targeting of CD161s in A-NK cells
    verified by flow cytometry
  • siRNA targeting of CD161s in A-NK does not result
    in reduced lysis of YAC-1
  • siRNA targeting of CD161B in A-NK cells results
    in reduced enhancement of lytic activity
    following A-NKDC co-culture

45
Mechanisms of Immune Evasion by Tumors
  • Department of Pathology Department of
    Neurological Surgery
  • William H. Chambers, Ph.D. Hideho Okada, M.D.,
    Ph.D.
  • Tianbing Yang, Ph.D. Ian F. Pollack, M.D.
  • Katy Webb Department of Immunology
  • Lorissa Figallo Sean Ryan
  • Department of Psychology Molecular Genetics and
    Biochemistry
  • Melanie Flint, Ph.D. Paul D. Robbins, Ph.D.
  • Dept.Cell Biol. Physiol./CBI Department of
    Neurobiology
  • Simon Watkins, Ph.D. Carl Lagenaur, Ph.D.
  • NSABP/UPCI Biostatistics Stanford University
  • Doug Potter, Ph.D. Sheri Krams, Ph.D.
  • John Bryant, Ph.D. Christine Hsieh

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