Immunotherapy for Infectious Diseases

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Immunopathogenesis of HIV Disease 159 With the development of immune-based therapies given with a background of potent antiviral therapy, and the ensuing rate of disease progression being as low as 1% per year or less, surrogate marker end points are essential. At the same time, although interventions that may result in change in viral load can be tested against that measure, it is quite conceivable that an intervention could confer significant immunologic benefit with little impact on viral load. Interventions that reverse immune dysregulation, increase CD4� T-cell levels, modulate excessive immune activation, or decrease apoptosis all might fall into this category. Validation of appropriate surrogate markers for immune-based therapies is the next hurdle in the advancement of this field. The choice of the population in which to test interventions is also an important consideration in clinical trial design. Patients with advanced disease, who have failed potent antiretroviral therapy, are eager to find alternate therapies, and their outcome might be relatively quickly learned. Unfortunately, many of the interventions being tried are the least effective and most toxic in subjects with advanced disease. Populations with a more intact immune response are therefore currently favored for trials of immune-based therapies. At the same time, if surrogate markers are being relied on for end points, there must be something to measure in the population chosen. For example, if change in viral load is chosen, then either the subjects must not have their viral load suppressed below the level of detection to begin with, or must have a likelihood of sufficient numbers of participants to experience viral breakthrough to be able to measure benefit from the intervention. An alternate model being explored is to withdraw therapy at some time and measure the rate or the magnitude of viral load resurgence as an end point. The possible risks to participants of this study design are being carefully examined. Further complicating the design of clinical trials is the rapid evolution of the standard of care of HIV disease. In trials that may take years to develop, enroll, and then follow to end points, care must be devoted to considering incorporation of the use of new antiviral drugs, new measures of efficacy of therapy, and new techniques for determining suitable antiviral regimens. (Examples are the routine use of potent antiretroviral cocktails, plasma viral load for assessing efficacy of therapy, and screening for antiviral resistance.) Otherwise, the outcome of the trial may not be relevant in the context of the current standard of care at the trial’s conclusion. Ethical considerations are extremely important in clinical trial design. Consideration must be given not only to the risk to the individual participant but also to the benefit to the community from which participants are recruited. In the United States, for instance, consideration must be given to including women and minorities in the participants in clinical trials and to not unnecessarily barring participation by pregnant women. The greatest challenge is in designing trials suitable for developing countries. The data gathered from such trials must be relevant to the population of that country and the prospect must exist for the therapy being tested to be available there if found to be effective. An exquisite tension exists between the dire need for therapies in developing nations and the barriers of cost that may be insurmountable. The unavailability of potent antiretroviral therapy in developing nations and the rapid rate of HIV disease progression still seen there makes this setting suitable for therapeutic trials with clinical end points. However, the lack of therapeutic options outside the clinical trials mechanism makes this group especially vulnerable to exploitation, and careful ethical review of clinical trials planned for developing nations is extremely important.
160 Fox REFERENCES 1. UNAIDS. Report on the Global HIV/AIDS Epidemic, December, 1998. UNAIDS, 1998. 2. Gao F, Baile E, Robertson DL, et al. Origin of HIV-1 in the chimpanzee Pan troglodytes. Nature 1999; 397:436–441. 3. Quinn T. Global burden of the HIV pandemic. Lancet 1996; 348:99–106. 4. Centers for Disease Control and Prevention, unpublished data. 5. Perelson AS, Neumann AU, Markowitz M, et al. HIV dynamics in vivo: virion clearance rate, infected cell life-span, and viral generation time. Science 1996; 271:1582–1586. 6. Panteleo G, Fauci AS. New concepts in the immunopathogenesis of HIV infection. Annu Rev Microbiol 1996; 50:825–845. 7. Panteleo G, Demarest JF, Schacker T, et al. The quantitative nature of the primary immune response is a prognosticator of disease progression independent of the initial level of plasma viremia. Proc Natl Acad Sci USA 1997; 94:254–258. 8. Kirchoff F, Greenough TC, Brettler DB, et al. Brief report of the absence of intact nef sequences in a long-term noprogressing survivor of HIV-1 infection. N Engl J Med 1995; 332:228–232. 9. Deacon NJ, Tsykin A, Slomon A, et al. Genomic structure of an attenuated quasi species of HIV-1 from a blood transfusion donor and recipients. Science 1995; 270:988–991. 10. Salvi R, Garbuglia AR, Di Caro A, et al. Grossly defective nef gene sequences in a human immunodeficiency virus type-1-seropositive long-term nonprogressor. J Virol 1998; 72:3646–3657. 11. Houria H, Caillat-Zucman S, Lebuanec H, et al. New class I and II HLA alleles strongly associated with opposite patterns of progression to AIDS. J Immunol 1999; 162:6942–6946. 12. D’Souza MP, Harden VA. Chemokines and HIV second receptors. Confluence of two fields generates optimism in AIDS research. Nat Med 1996; 2:1293–1300. 13. Dragic T, Litwin V, Allaway GP, et al. HIV-1 entry inot CD4� cells is mediated by the chemokine receptor CC-CKR-5. Nature 1996; 381:667–673. 14. Doranz BJ, Rucker J, Yi Y, et al. A dual-tropic primary HIV-1 isolate that uses fusin and the beta-chemokine receptors CKR-5. CKR-3, CKR-2b as fusion co-factors. Cell 1996; 85:1149–1158. 15. Choe H, Farzan M, Sun Y, et al. The beta-chemokine receptors CCR3 and CCR5 facilitate infection by primary HIV-1 isolates. Cell 1996; 85:1135–1148. 16. Alkhatib G, Combardiere C, Broder CC, et al. CC CKR5: a RANTES, MIP1alpha, MIP- 1beta receptor as a fusion cofactor for macrophage-tropic HIV-1. Science 1996; 272:1955–1958. 17. Deng H, Liu R, Ellmeier W, et al. Identification of a major co-receptor for primary isolates of HIV-1. Nature 1996; 381:661–666. 18. Feng Y, Broder CC, Kennedy PE, Berger EA. HIV-1 entry cofactor: functional cDNA cloning of a seven-transmembrane, G protein-coupled receptor. Science 1996; 272:872–877. 19. Bleul CC, Farzan M, Choe H, et al. The lymphocyte chomeattractant SDF-1 is a ligand for LESTR/fusin and blocks HIV-1 entry. Nature 1996; 382:829–833. 20. Oberlin E, Amara A, Bachelerie F, et al. The CXC chemokine SDF-1 is the ligand for LESTR/fusin and prevents infection by T cell line-adapted HIV-1. Nature 1996; 382:833–835. 21. Liu R, Paxto WA, Choe S, et al. Homozygous defect in HIV-1 coreceptor accounts for resistance of some multiply-exposed individuals to HIV-1 infection. Cell 1996; 86:367–377. 22. Samson M, Libert F, Doranz BJ, et al. Resistance to HIV-1 infection in Caucasian individuals bearing mutant alleles of the CCR-5 chemokine receptor gene. Nature 1996; 382:722–725. 23. Dean M, Carrington M, Winkler C, et al. Genetic restriction of HIV-1 infection and progression to AIDS by a deletion allele of the CKR5 structural gene. Hemophilia Growth and
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Immunotherapy for Infectious Diseas
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In f e c t i o u s . D i s e a s e
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© 2002 Humana Press Inc. 999 River
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vi Preface I am grateful to all of
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viii Contents 11 Passive Immunother
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x Contributors BARBARA G. MATTHEWS,
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From: Immunotherapy for Infectious
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Humoral Immunity 5 Fig. 1. Humoral
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Humoral Immunity 7 Table 1 Properti
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Humoral Immunity 9 minal complement
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Humoral Immunity 11 ficity. In ligh
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Humoral Immunity 13 Fig. 7. VDJ joi
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Humoral Immunity 15 Fig. 9. Messeng
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Humoral Immunity 17 In contrast to
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Humoral Immunity 19 advantage to tr
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Humoral Immunity 21 32. Allman DM,
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Some Basic Cellular Immunology Prin
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Cellular Immunology Principles 25 i
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Cellular Immunology Principles 27 s
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Cellular Immunology Principles 29 d
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Cellular Immunology Principles 31 f
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Cellular Immunology Principles 33 F
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Cellular Immunology Principles 35 R
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Cellular Immunology Principles 37 1
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INTRODUCTION Immune Defense at Muco
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Immune Defense at Mucosal Surfaces
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II Molecular Basis for Immunotherap
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64 Kunert and Katinger IMMUNOGLOBUL
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66 Fig. 2. Monomeric, dimeric, and
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68 Kunert and Katinger Fig. 4. Humo
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70 Kunert and Katinger remove prote
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72 Kunert and Katinger Fig. 6. Diff
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74 Kunert and Katinger persons of a
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76 Kunert and Katinger that so-call
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78 Kunert and Katinger whereas sele
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80 Kunert and Katinger Different pr
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82 Kunert and Katinger HUMAN/MOUSE
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84 Kunert and Katinger are expresse
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86 Kunert and Katinger missing meta
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88 Kunert and Katinger Fig. 8. Sche
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90 Kunert and Katinger include a se
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92 Kunert and Katinger 32. Lee S, e
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94 Kunert and Katinger 72. Abbs IC,
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96 Kunert and Katinger 117. Wright
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Dendritic Cells 101 several organis
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Dendritic Cells 103 tion that infec
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Dendritic Cells 105 chaperones such
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Dendritic Cells 107 CD8� CTLs, th
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Page 124 and 125: Dendritic Cells 113 mouse pneumonit
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Page 128 and 129: INTRODUCTION Cytokines, Cytokine An
Page 130 and 131: Cytokines, Cytokine Antagonists, an
Page 140 and 141: Principles of Vaccine Development F
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Page 162 and 163: INTRODUCTION Immunopathogenesis of
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Page 183 and 184: 172 Connick 2. Delta Coordinating C
Page 185 and 186: 174 Connick 39. Hurni MA, Bohlen L,
Page 187 and 188: 176 Connick 76. Dolan M.J., Clerici
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Page 211 and 212: 200 Jacobson changes of gp120 alter
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Page 215 and 216: 204 Jacobson Table 2 Potential Prot
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210 Jacobson HUMAN STUDIES Polyclon
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212 Jacobson clinical isolates, whi
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214 Jacobson 22. Beasley RP, Hwang
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216 Jacobson 59. Yoshiyama H, Mo H,
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218 Jacobson 95. Prince AM, Reesink
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220 Jacobson 133. Stiehm ER, Lamber
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222 Kilby and Bucy Although clinica
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224 Kilby and Bucy can infect human
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226 Kilby and Bucy the proinflammat
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228 Kilby and Bucy CD3/CD28, and th
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230 Kilby and Bucy of viral replica
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232 Kilby and Bucy 21. Cao Y, Qin L
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234 Kilby and Bucy 64. Pantaleo G,
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236 Kilby and Bucy 101. Clements-Ma
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238 Dornburg and Pomerantz cells (5
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240 Dornburg and Pomerantz Fig. 2.
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242 Dornburg and Pomerantz domains
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244 Dornburg and Pomerantz GENETIC
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246 Dornburg and Pomerantz Fig. 5.
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248 Dornburg and Pomerantz 6. Balti
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Viral Infections Other than HIV 253
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Virus-Associated Malignancies 261 c
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Virus-Associated Malignancies 263 o
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Virus-Associated Malignancies 265 I
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Virus-Associated Malignancies 267 R
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Virus-Associated Malignancies 269 T
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Virus-Associated Malignancies 271 1
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Virus-Associated Malignancies 273 5
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Bacterial Infections and Sepsis 277
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284 Wallis and Johnson replication
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286 Wallis and Johnson Several stud
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288 Wallis and Johnson monocytes, a
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290 Wallis and Johnson peripheral b
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292 Wallis and Johnson (A. Hise and
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294 Wallis and Johnson infections,
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296 Wallis and Johnson 37. Boom WH.
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298 Wallis and Johnson 77. Ellner J
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300 Wallis and Johnson 113. Raad I,
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302 Wallis and Johnson 154. Anonymo
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304 Table 1 Major Fungal Infections
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306 Casadevall species suggest that
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308 Casadevall transfusions from G-
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310 Casadevall Table 3 Augmentation
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312 Casadevall There has been some
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314 Casadevall effective in achievi
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316 Casadevall CONCLUSION AND FUTUR
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318 Casadevall 16. Boutati EI, Anai
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320 Casadevall 52. Gallin JI, Malec
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322 Casadevall 91. Kowanko IC, Ferr
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324 Index Blastomycosis, see Fungal
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326 Index C-type retrovirus vectors
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328 Index K Klebsiella, intravenous
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330 Index Vaccine Recombinant vecto
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Infectious Disease IMMUNOTHERAPY FO
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