46 research outputs found
Investigating the Effects of a Hydrolytically Stable Hapten and a Th1 Adjuvant on Heroin Vaccine Performance
We challenged the performance of our previous heroin
vaccine with
a similar vaccine containing a more hydrolytically stable hapten analogue
and a Th1 adjuvant (CpG ODN). Our results indicate that the elements
of our previous vaccine are essential for its anti-heroin potency,
i.e., a chemically labile hapten and an exclusively Th2 humoral response
elicited by alum. Such design elements are critical for producing
next-generation heroin vaccines
Investigating Hapten Clustering as a Strategy to Enhance Vaccines against Drugs of Abuse
Vaccines for drugs of abuse have
yet to achieve full clinical relevance,
largely due to poor/inconsistent immune responses in patients. The
use of multivalent scaffolding as a means to tailor drug–hapten
density and clustering was examined in the context of drug-immune
response modulation. A modular trivalent hapten containing a diglycine
spacer, triAM1Â(Gly)<sub>2</sub>, was synthesized and shown to elicit
anti-nicotine antibodies at equivalent affinity and concentration
to the monovalent AM1 analog, despite in this instance having a lower
effective hapten density. Augmenting this data, the corresponding
monovalent hapten AM1Â(Gly)<sub>2</sub> resulted in enhanced antibody
affinity and concentration. Drug-hapten clustering represents a new
vaccine paradigm, and, while examined only in the context of nicotine,
it should be readily translatable to other drugs of abuse
An Antidote for Acute Cocaine Toxicity
Not only has immunopharmacotherapy grown into a field
that addresses
the abuse of numerous illicit substances, but also the treatment methodologies
within immunopharmacotherapy have expanded from traditional active
vaccination to passive immunization with anti-drug monoclonal antibodies,
optimized mAb formats, and catalytic drug-degrading antibodies. Many
laboratories have focused on transitioning distinct immunopharmacotherapeutics
to clinical evaluation, but with respect to the indication of cocaine
abuse, only the active vaccine TA-CD, which is modeled after our original
cocaine hapten GNC, has been carried through
to human clinical trials. The successful
application of murine mAb GNC92H2 to the reversal of cocaine overdose
in a mouse model prompted investigations of human immunoglobulins
with the clinical potential to serve as cocaine antidotes. We now
report the therapeutic utility of a superior clone, human mAb GNCgzk
(<i>K</i><sub>d</sub> = 0.18 nM), which offers a 10-fold
improvement in cocaine binding affinity. The GNCgzk manifold was engineered
for rapid cocaine clearance, and administration of the FÂ(ab′)<sub>2</sub> and Fab formats even after the appearance of acute behavioral
signs of cocaine toxicity granted nearly complete prevention of lethality.
Thus, contrary to the immunopharmacotherapeutic treatment of drug
self-administration, minimal antibody doses were shown to counteract
the lethality of a molar excess of circulating cocaine. Passive vaccination
with drug-specific antibodies represents a viable treatment strategy
for the human condition of cocaine overdose
Modulating Cocaine Vaccine Potency through Hapten Fluorination
Cocaine addiction is a long-lasting relapsing illness
characterized
by cycles of abuse, abstinence, and reinstatement, and antibody-based
therapies could be a powerful therapeutic approach. Herein, we explored
the possibility of using halogenated cocaine haptens to enhance the
immunological properties of anti-cocaine vaccines. Three fluorine-containing
cocaine haptens (GNF, GNCF and GN5F) and one chlorine-containing cocaine
hapten (GNCl) were designed and synthesized, based upon the chemical
scaffold of the only hapten that has reached clinical trials, succinyl
norcocaine (SNC). Hapten GNF was found to retain potent cocaine affinity,
and also elicit antibodies in a higher concentration than the parent
structure SNC. Our data suggests that not only could strategic hapten
fluorination be useful for improving upon the current cocaine vaccine
undergoing clinical trials, but it may also be a valuable new approach,
with application to any of the vaccines being developed for the treatment
of drugs of abuse
A New Strategy for Smoking Cessation: Characterization of a Bacterial Enzyme for the Degradation of Nicotine
Smoking is the leading cause of preventable
diseases; thus, effective
smoking cessation aids are crucial for reducing the prevalence of
cigarette smoking and smoking-related illnesses. In our current campaign
we offer a nicotine-degrading enzyme from <i>Pseudomonas putida</i>, NicA2, a flavin-containing protein. To explore its potential, a
kinetic evaluation of the enzyme was conducted, which included determination
of <i>K</i><sub>m</sub>, <i>k</i><sub>cat</sub>, buffer/serum half-life, and thermostability. Additionally, the
catabolism profile of NicA2 was elucidated to assess the potential
toxicity of the nicotine-derived products. In characterizing the enzyme,
a favorable biochemical profile of the enzyme was discovered, making
NicA2 a prospective therapeutic candidate. This approach provides
a new avenue for the field of nicotine addiction therapy
Structural Analysis Provides Mechanistic Insight into Nicotine Oxidoreductase from <i>Pseudomonas putida</i>
The first structure of nicotine oxidoreductase
(NicA2) was determined
by X-ray crystallography. <i>Pseudomonas putida</i> has
evolved nicotine-degrading activity to provide a source of carbon
and nitrogen. The structure establishes NicA2 as a member of the monoamine
oxidase family. Residues 1–50 are disordered and may play a
role in localization. The nicotine-binding site proximal to the isoalloxazine
ring of flavin shows an unusual composition of the classical aromatic
cage (W427 and N462). The active site architecture is consistent with
the proposed binding of the deprotonated form of the substrate and
the flavin-dependent oxidation of the pyrrolidone C–N bond
followed by nonenzymatic hydrolysis
An Advance in Prescription Opioid Vaccines: Overdose Mortality Reduction and Extraordinary Alteration of Drug Half-Life
Prescription
opioids (POs) such as oxycodone and hydrocodone are
highly effective medications for pain management, yet they also present
a substantial risk for abuse and addiction. The consumption of POs
has been escalating worldwide, resulting in tens of thousands of deaths
due to overdose each year. Pharmacokinetic strategies based upon vaccination
present an attractive avenue to suppress PO abuse. Herein, the preparation
of two active PO vaccines is described that were found to elicit high-affinity
antiopioid antibodies through a structurally congruent drug-hapten
design. Administration of these vaccines resulted in a significant
blockade of opioid analgesic activity, along with an unprecedented
increase in drug serum half-life and protection against lethal overdose
Development of an Effective Monoclonal Antibody against Heroin and Its Metabolites Reveals Therapies Have Mistargeted 6‑Monoacetylmorphine and Morphine over Heroin
The opioid epidemic is a global public health crisis
that has failed
to abate with current pharmaceutical treatments. Moreover, these FDA-approved
drugs possess numerous problems such as adverse side effects, short
half-lives, abuse potential, and recidivism after discontinued use.
An alternative treatment model for opioid use disorders is immunopharmacotherapy,
where antibodies are produced to inhibit illicit substances by sequestering
the drug in the periphery. Immunopharmacotherapeutics against heroin
have engaged both active and passive vaccines targeting heroin’s
metabolites, 6-monoacetylmorphine (6-AM) and morphine, since decades
of research have stated that heroin’s psychoactive and lethal
effects are mainly attributed to these compounds. However, concerted
efforts to develop effective immunopharmacotherapies against heroin
abuse have faced little clinical advancement, suggesting a need for
reassessing drug target selection. To address this issue, four unique
monoclonal antibodies were procured with distinct affinity to either
heroin, 6-AM, or morphine. Examination of these antibodies through in vitro and in vivo tests revealed monoclonal
antibody 11D12 as the optimal therapeutic and provided crucial insights
into the key chemical species to target for blunting heroin’s
psychoactive and lethal effects. These findings offer clarification
into the problematic attempts of therapeutics targeting heroin’s
metabolites and provide a path forward for future heroin immunopharmacotherapy
development
Probing BoNT/A Protease Exosites: Implications for Inhibitor Design and Light Chain Longevity
Botulinum
neurotoxin serotype A (BoNT/A) is one of the most lethal
toxins known. Its extreme toxicity is due to its light chain (LC),
a zinc protease that cleaves SNAP-25, a synaptosome-associated protein,
leading to the inhibition of neuronal activity. Studies on BoNT/A
LC have revealed that two regions, termed exosites, can play an important
role in BoNT catalytic activity. A clear understanding of how these
exosites influence neurotoxin catalytic activity would provide a critical
framework for deciphering the mechanism of SNAP-25 cleavage and the
design of inhibitors. Herein, based on the crystallographic structure
of BoNT/A LC complexed with its substrate, we designed an α-exosite
binding probe. Experiments with this unique probe demonstrated that
α-exosite binding enhanced both catalytic activity and stability
of the LC. These data help delineate why α-exosite binding is
needed for SNAP-25 cleavage and also provide new insights into the
extended lifetime observed for BoNT/A LC <i>in vivo</i>
Methamphetamine Vaccines: Improvement through Hapten Design
Methamphetamine (MA)
addiction is a serious public health problem,
and current methods to abate addiction and relapse are currently ineffective
for mitigating this growing global epidemic. Development of a vaccine
targeting MA would provide a complementary strategy to existing behavioral
therapies, but this has proven challenging. Herein, we describe optimization
of both hapten design and formulation, identifying a vaccine that
elicited a robust anti-MA immune response in mice, decreasing methamphetamine-induced
locomotor activity