Your search keyword '"Marsida Kallupi"' showing total 7 results

1. Cocaine addiction-like behaviors are associated with long-term changes in gene regulation, energy metabolism, and GABAergic inhibition within the amygdala

Author

Jessica L. Zhou, Giordano de Guglielmo, Aaron J. Ho, Marsida Kallupi, Hai-Ri Li, Apurva S. Chitre, Lieselot LG Carrette, Olivier George, Abraham A. Palmer, Graham McVicker, and Francesca Telese

Abstract

The amygdala contributes to negative emotional states associated with relapse to drug seeking, but the cell type-specific gene regulatory programs that are involved in addiction are unknown. Here we generate an atlas of single nucleus gene expression and chromatin accessibility in the amygdala of outbred rats with low and high cocaine addiction-like behaviors following a prolonged period of abstinence. Between rats with different addiction indexes, there are thousands of cell type-specific differentially expressed genes and these are enriched for molecular pathways including GABAergic synapse in astrocytes, excitatory, and somatostatin neurons. We find that rats with higher addiction severity have excessive GABAergic inhibition in the amygdala, and that hyperpolarizing GABAergic transmission and relapse-like behavior are reversed by pharmacological manipulation of the metabolite methylglyoxal, a GABAA receptor agonist. By analyzing chromatin accessibility, we identify thousands of cell type-specific chromatin sites and transcription factor (TF) motifs where accessibility is associated with addiction-like behaviors, most notably at motifs for pioneer TFs in the FOX, SOX, and helix-loop-helix families.

Published

2022

2. Individual differences in oxycodone addiction-like behaviors in a large cohort of heterogeneous stock (HS) rats

Author

Marsida Kallupi, Giordano de Guglielmo, Lieselot LG Carrette, Sierra Simpson, Jenni Kononoff, Adam Kimbrough, Lauren C Smith, Kokila Shankar, Alicia Avelar, Dana Conlisk, Molly Brennan, Lani Tieu, Sharona Sedighim, Brent Boomhower, Lisa Maturin, McKenzie J Fannon, Angelica Martinez, Caitlin Crook, Selen Dirik, Nathan Velarde, Paul Schweitzer, Selene Bonnet-Zahedi, Dyar N. Othman, Benjamin Sichel, Kwynn Guess, Beverly Peng, Andrew S. Hu, Lucas E. Chun, Kristel Milan, Justin Lau, Yicen Zheng, Ashley Vang, Leah C. Solberg Woods, Abraham A. Palmer, and Olivier George

Abstract

Family and twin studies demonstrate that genetic factors determine 20-60% of the vulnerability to opioid use disorder. However, the genes/alleles that mediate the risk of developing addiction-related behaviors, including the sensitivity to the analgesic efficacy of opioids, the development of tolerance, dependence, and escalation of oxycodone taking and seeking, have been ill-defined, thus hindering efforts to design pharmacological interventions to enable precision medicine strategies. Here we characterized oxycodone addiction-like behaviors in heterogeneous stock (HS) rats, that show high genetic diversity that mimics the high genetic variability in humans. HS rats were allowed to self-administer oxycodone for two h/daily for four days (ShA) and then moved to 12h/daily (LgA) for 14 days. Animals were screened for motivation to self-administer oxycodone using a progressive-ratio (PR) schedule of reinforcement and for the development of withdrawal-induced hyperalgesia and tolerance to the analgesic effects of oxycodone using the von-Frey and tail immersion tests, respectively. To reduce cohort-specific effects, we used cohorts of 46-60 rats and normalized the response level within cohorts using a Z-score. To take advantage of the four opioid-related behaviors and further identify subjects that are consistently vulnerable vs. resilient to compulsive oxycodone use, we computed an Addiction Index by averaging normalized responding (Z-scores) for the four behavioral tests. Results showed high individual variability between vulnerable and resilient rats, likely to facilitate the detection of gene variants associated with vulnerable vs. resilient individuals. Such data will have considerable translational value for designing follow-up studies in humans.

Published

2022

3. Identification of individual differences in response to methadone, buprenorphine, and naltrexone in animal models of opioid use disorder

Author

Marsida Kallupi, Giordano de Guglielmo, Dana Conlisk, Molly Brennan, Lani Tieu, Sharona Sedighim, Brent Boomhower, Lauren C Smith, Kokila Shankar, Lieselot LG Carrette, Sierra Simpson, Alicia Avelar, Lisa Maturin, Angelica Martinez, Ran Qiao, Selen Dirik, Caitlin Crook, Selene Bonnet-Zahedi, Mohini R. Iyer, Corrine E. Blucher, McKenzie J Fannon, Leah C. Solberg Woods, Abraham A. Palmer, and Olivier George

Abstract

RationaleCurrent medications for opioid use disorder include buprenorphine, methadone, and naltrexone. While these medications show significant efficacy in reducing craving and opioid use, there are substantial individual differences in response to these treatments in humans. The reason for such difference is poorly known.ObjectivesHere, we tested the hypothesis that similar individual differences may be observed in a large population of heterogenous stock rats, that have been bred to maximize genetic diversity, using a behavioral paradigm relevant to opioid use disorder.MethodsOver 500 rats were given intermittent (4d/week) and extended access (12h/day) to oxycodone self-administration for 14 sessions to establish oxycodone dependence and escalation of intake. We then measured the effect of buprenorphine (0.5mg/kg), methadone (3mg/kg) and naltrexone (3mg/kg) on the motivation to self-administer oxycodone by using a progressive ratio schedule of reinforcement.ResultsWe found that naltrexone and buprenorphine significantly decreased motivation to oxycodone rewards. While naltrexone reduced oxycodone intake in both males and females, systemic administration with buprenorphine reduced progressive ratio responses only in males. Methadone reduced motivation to oxycodone self-administration in nearly 25% of the population, without reaching statical significance. Our results showed that the efficacy of these medications depends on the severity of addiction like behaviors, indicated by the addiction index.ConclusionsThese results demonstrate individual differences in response to medications to treat opioid use disorder in a genetically diverse population of rats.

Published

2022

4. Identification of pre-existing microbiome and metabolic vulnerabilities to escalation of oxycodone self-administration and identification of a causal role of short-chain fatty acids in addiction-like behaviors

Author

Sierra Simpson, Adam Kimbrough, Gregory Peters, Emma Wellmeyer, Rio Mclellan, Natalie Walker, Haoyu Jia, Sharon Hu, Mohini Iyer, Varshini Sathish, Sharona Sedighim, Marsida Kallupi, Molly Brennan, Lisa Maturin, Talyn Hughes, Tristin Xie, Veronika Espinoza, Lieselot Carrette, Lauren C. Smith, Jonathan Seaman, Leah C. Solberg Woods, Abraham A. Palmer, Giordano DeGuglielmo, and Olivier George

Abstract

The gut brain axis is thought to play a role in behavior and physiological responses through chemical, immunological, and metabolite signaling. Antibiotics, diet, and drugs can alter the transit time of gut contents as well as the makeup of the microbiome. Heterogeneity in genetics and environment are also well-known factors involved in the initiation and perpetuation of substance use disorders. Few viable genetic or biological markers are available to identify individuals who are at risk of escalating opioid intake. Primarily, the addiction field has focused on the nervous system, limiting the discovery of peripheral factors that contribute to addiction. To address this gap, we characterized the microbiome before and after drug exposure, and after antibiotics depletion in male and female heterogenous stock rats to determine if microbiome constituents are protective of escalation. We hypothesized that individuals that are prone to escalation of opioid self-administration will have distinct microbial and metabolic profiles. The fecal microbiome and behavioral responses were measured over several weeks of oxycodone self-administration and after antibiotic treatment. Antibiotic treatment reduces circulating short-chain fatty acids (SCFA) by depleting microbes that ferment fiber into these essential signaling molecules for the gut-brain axis. Depletion of the microbiome increased oxycodone self-administration in a subpopulation of animals (Responders). Supplementation of SCFAs in antibiotic depleted animals decreased elevated oxycodone self-administration. Phylogenetic functional analysis reveals distinct metabolic differences in the subpopulations of animals that are sensitive to antibiotic depletion and animals rescued by SCFA supplementation. In conclusion, this study identifies pre-existing microbiome and metabolic vulnerabilities to escalation of oxycodone self-administration, demonstrates that escalation of oxycodone self-administration dysregulates the microbiome and metabolic landscape, and identifies a causal role of short-chain fatty acids in addiction-like behaviors.

Published

2022

5. Vaping nicotine-containing electronic cigarettes produces addiction-like behaviors and cardiopulmonary abnormalities in rats

Author

Jamie Barr, Olivier George, Xin Sun, Lieselot L. G. Carrette, Giordano de Guglielmo, Sharona Sedighim, Marsida Kallupi, Lauren C. Smith, Nathan Velarde, Mike Klodnicki, Abigail Jaquish, Lani Tieu, and Yujuan Su

Subjects

Drug, medicine.medical_specialty, media_common.quotation_subject, medicine.medical_treatment, law.invention, Nicotine, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, law, Medicine, Nicotine dependence, Varenicline, Psychiatry, 030304 developmental biology, media_common, 0303 health sciences, Health professionals, business.industry, Addiction, medicine.disease, 3. Good health, chemistry, Smoking cessation, business, Electronic cigarette, 030217 neurology & neurosurgery, medicine.drug

Abstract

The debate about electronic cigarettes has divided healthcare professionals, policymakers, and communities. Central points of disagreement are whether vaping electronic cigarettes are addictive and whether they produce major pulmonary complications. We developed a novel model of nicotine vapor self-administration in rats and found that rats voluntarily exposed themselves to nicotine vapor to the point of reaching blood nicotine levels that are similar to humans, exhibiting both addiction-like behaviors and cardiopulmonary abnormalities. The smoking cessation drug varenicline decreased electronic cigarette self-administration. These findings confirm the addictive properties and harmful effects of nicotine vapor and identify a potential medication for the treatment of electronic cigarette addiction.One Sentence SummaryVaping nicotine-containing electronic cigarettes produces cardiopulmonary abnormalities, nicotine dependence and addiction-like behaviors, which are reduced by the smoking cessation drug varenicline.

Published

2019

6. Characterization of the brain functional architecture of psychostimulant withdrawal using single-cell whole brain imaging

Author

Andres Collazo, Sierra Simpson, Lauren C. Smith, Adam Kimbrough, Olivier George, and Marsida Kallupi

Subjects

Modularity (networks), business.industry, Traumatic brain injury, Addiction, media_common.quotation_subject, Methamphetamine, medicine.disease, Substance abuse, Nicotine, Neuroimaging, medicine, Dementia, business, Neuroscience, medicine.drug, media_common

Abstract

Numerous brain regions have been identified as contributing to addiction-like behaviors, but unclear is the way in which these brain regions as a whole lead to addiction. The search for a final common brain pathway that is involved in addiction remains elusive. To address this question, we used male C57BL/6J mice and performed single-cell whole-brain imaging of neural activity during withdrawal from cocaine, methamphetamine, and nicotine. We used hierarchical clustering and graph theory to identify similarities and differences in brain functional architecture. Although methamphetamine and cocaine shared some network similarities, the main common neuroadaptation between these psychostimulant drugs was a dramatic decrease in modularity, with a shift from a cortical- to subcortical-driven network, including a decrease in total hub brain regions. These results demonstrate that psychostimulant withdrawal produces the drug-dependent remodeling of functional architecture of the brain and suggest that the decreased modularity of brain functional networks and not a specific set of brain regions may represent the final common pathway that leads to addiction.Significance StatementA key aspect of treating drug abuse is understanding similarities and differences of how drugs of abuse affect the brain. In the present study we examined how the brain is altered during withdrawal from psychostimulants. We found that each drug produced a unique pattern of activity in the brain, but that brains in withdrawal from cocaine and methamphetamine shared similar features. Interestingly, we found the major common link between withdrawal from all psychostimulants, when compared to controls, was a shift in the broad organization of the brain in the form of reduced modularity. Reduced modularity has been shown in several brain disorders, including traumatic brain injury, and dementia, and may be the common link between drugs of abuse.

Published

2019

7. Deep brain stimulation of the nucleus accumbens shell does not decrease cocaine self-administration in cocaine-dependent rats but increases GluR1/GluA1 in the central nucleus of the amygdala

Author

Olivier George, Guglielmo Gd, Philippe A. Melas, Johanna S. Qvist, Jenni Kononoff, Marsida Kallupi, and Eric R. Kandel

Subjects

Deep brain stimulation, medicine.medical_treatment, media_common.quotation_subject, Craving, AMPA receptor, Nucleus accumbens, Pharmacology, 03 medical and health sciences, 0302 clinical medicine, mental disorders, medicine, 030304 developmental biology, media_common, 0303 health sciences, business.industry, Central nucleus of the amygdala, Addiction, Abstinence, 3. Good health, surgical procedures, operative, nervous system, medicine.symptom, Self-administration, business, 030217 neurology & neurosurgery, psychological phenomena and processes

Abstract

BackgroundCocaine addiction is a major public health problem. Despite decades of intense research, no effective treatments are available. Both preclinical and clinical studies of drug addiction strongly suggest that the nucleus accumbens (NAcc) is a viable target for deep brain stimulation (DBS).ObjectiveAlthough previous studies have shown that DBS of the NAcc decreases cocaine seeking and reinstatement, the effects of DBS on cocaine intake in cocaine-dependent animals have not yet been investigated.MethodsRats were made cocaine-dependent by allowing them to self-administer cocaine in long-access sessions (6 h, 0.5 mg/kg/infusion). The effects of high-frequency DBS of the NAcc shell on cocaine intake was then studied. Furthermore, cocaine-induced locomotor activity, irritability-like behavior during cocaine abstinence and the levels of the α-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptor subunits 1 and 2 (GluR1/GluA1 and GluR2/GluA2) after DBS were investigated.ResultsContrary to our expectations, DBS of the NAcc shell induced a slight increase in both cocaine self-administration and cocaine-induced locomotor activity. In addition, 18 h into cocaine withdrawal, we found that DBS decreased irritability-like behavior. We also found that DBS-induced a robust increase in both cytosolic and synaptosomal levels of GluR1, but not GluR2, specifically in the central nucleus of the amygdala but not in other brain regions.ConclusionsThese preclinical results with cocaine-dependent animals do not support high-frequency DBS of the NAcc shell as a therapeutic approach for the treatment of cocaine addiction in active cocaine users. However, the decrease in irritability-like behavior during cocaine abstinence, together with previous findings showing that DBS of the NAcc shell reduces the reinstatement of cocaine seeking in abstinent animals, warrants future investigations of DBS as a treatment for negative emotional states and craving during abstinence.HighlightsHigh-frequency DBS of the NAcc shell for the treatment of cocaine addiction is proposedDBS of the NAcc shell does not decrease cocaine intake in cocaine-dependent ratsDBS increases the level of GluR1 specifically in the central nucleus of the amygdala

Published

2018