Monoclonal Antibody Therapies against Anthrax
Abstract
:1. Anthrax Disease and Its Virulence Determinants
2. The Limitations of Currently Recommended Post-Exposure Treatment
3. Passive Immunization through Treatment with mAbs
3.1. Current Status of Anti-Anthrax mAb Development
3.1.1. Anti-PA mAbs
mAb | Origin | Epitope (Domain) | Neutralizing Mechanism | Animal Model for in vivo Protection | Reference |
---|---|---|---|---|---|
Abthrax | Human | IV | Inhibition of receptor binding | Rat, rabbit and monkey | [37] |
AVP-21D9 | Human | III | Interference with toxin assembly | Rat 1 and rabbit 2 | [38,43] |
ETI-204 | Humanized | IV | Inhibition of receptor binding | Rabbit | [40] |
MDX 1303 | Human | III | Disruption of preformed PA heptamer | Rabbit and monkey 3 | [39] |
IQNPA | Human | IV | Inhibition of receptor binding | Mouse 4 | [35] |
W1 | Chimpanzee | IV | Inhibition of receptor binding | Rat and mouse | [36] |
mAb | Affinity (Kd) | Antibody dose for 100% protection | Reference |
---|---|---|---|
Abthrax | 2.78 nM | 1.5 mg/kg in rat 2, 40 mg/kg in rabbit 3, 40 mg/kg in monkey 4 | [37] |
ETI-204 | 0.33 nM | 4 mg/kg in rabbit 3 | [40] |
IQNPA | ND 1 | 7.2 mg/kg in mouse 5 | [35] |
W1 | 0.04 nM | 0.021 mg/kg in rat 2, 1.6 mg/kg in mouse 6 | [36] |
3.1.2. Anti-LF mAbs
mAb | Origin | Affinity (Kd) | Epitope (Domain) | In vitro Neutralization (EC50) | In vivo Neutralization | Reference |
---|---|---|---|---|---|---|
LF8 | Mouse | ND 1 | I | + (ND) 3 | Athymic nude mouse 4 | [55] |
9A11 | Mouse | 70.1 nM | ND | 1.3 nM | Balb/C mouse 5 | [33] |
10G3 | Mouse | 20 nM 2 | I | + (ND) | Fischer 344 rat | [56] |
2E7 | Mouse | 87 nM 2 | I | + (ND) | Fischer 344 rat | [56] |
3F6 | Mouse | 40 nM 2 | I | + (ND) | Fischer 344 rat | [56] |
5B13B1 | Mouse | 2.62 nM | III | 1.4 nM | Fischer 344 rat | [57] |
3C16C3 | Mouse | 8.18 nM | III | 4.2 nM | Fischer 344 rat | [57] |
IQNLF | Human | ND | I | 0.1 nM | A/J mouse | [35] |
LF10E | Chimpanzee | 0.69 nM | I | 0.1 nM | Fischer 344 rat and A/J mouse | [54] |
LF11H | Chimpanzee | 7.4 nM | I | 400 nM | Fischer 344 rat | [54] |
3.1.3. Anti-EF mAbs
mAb | Origin | Affinity (Kd) 1 | In Vitro Neutralization 2 | In Vivo Neutralization 3 | Reference |
---|---|---|---|---|---|
9F5 | Mouse | 2 nM | Yes | ND | [58] |
1E6 | Mouse | 5 nM | Yes | ND | [58] |
7G10 | Mouse | 9 nM | Yes | ND | [58] |
9F3 | Mouse | 830 nM | Yes | No | [60] |
EF13D | Chimpanzee | 0.05–0.12 nM | Yes | Yes | [59] |
3.1.4. Anti-Capsule mAbs
mAb | Origin | Affinity (Kd) 1 | Antibody Dose for 100% Protection 2 | Reference |
---|---|---|---|---|
F26G3 | Mouse | 370 nM | 2–4 mg | [69] |
F24F | Mouse | 500 nM | 2 mg | [69] |
F26G4 | Mouse | 510 nM | 2–4 mg | [69] |
4C | Chimpanzee | 36 nM | 0.3 mg | [70] |
11D | Chimpanzee | 64 nM | 0.3–1 mg | [70] |
3.2. Maximizing the Efficacy of Antibody Therapy by Targeting Multiple Epitopes
4. Conclusions
Conflicts of Interest
Acknowledgements
References
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Chen, Z.; Moayeri, M.; Purcell, R. Monoclonal Antibody Therapies against Anthrax. Toxins 2011, 3, 1004-1019. https://doi.org/10.3390/toxins3081004
Chen Z, Moayeri M, Purcell R. Monoclonal Antibody Therapies against Anthrax. Toxins. 2011; 3(8):1004-1019. https://doi.org/10.3390/toxins3081004
Chicago/Turabian StyleChen, Zhaochun, Mahtab Moayeri, and Robert Purcell. 2011. "Monoclonal Antibody Therapies against Anthrax" Toxins 3, no. 8: 1004-1019. https://doi.org/10.3390/toxins3081004
APA StyleChen, Z., Moayeri, M., & Purcell, R. (2011). Monoclonal Antibody Therapies against Anthrax. Toxins, 3(8), 1004-1019. https://doi.org/10.3390/toxins3081004