Healthy VolunteersLSDPlacebo

A Single Dose of LSD Does Not Alter Gene Expression of the Serotonin 2A Receptor Gene (HTR2A) or Early Growth Response Genes (EGR1-3) in Healthy Subjects

This double-blind, placebo-controlled crossover study (n=15) investigated whether a single dose of LSD (100 µg) alters gene expression in whole blood as a marker of tolerance. Results show no significant changes in the expression of the 5-HT2A receptor gene or early growth response genes (EGR1-3) at 1.5 or 24 hours post-administration.

Authors

  • Matthias Liechti
  • Stefan Borgwardt
  • Patrick Dolder

Published

Frontiers in Pharmacology
individual Study

Abstract

Rationale

Renewed interest has been seen in the use of lysergic acid diethylamide (LSD) in psychiatric research and practice. The repeated use of LSD leads to tolerance that is believed to result from serotonin (5-HT) 5-HT2A receptor downregulation. In rats, daily LSD administration for 4 days decreased frontal cortex 5-HT2A receptor binding. Additionally, a single dose of LSD acutely increased expression of the early growth response genes EGR1 and EGR2 in rat and mouse brains through 5-HT2A receptor stimulation. No human data on the effects of LSD on gene expression has been reported. Therefore, we investigated the effects of single-dose LSD administration on the expression of the 5-HT2A receptor gene (HTR2A) and EGR1-3 genes.

Methods

mRNA expression levels were analyzed in whole blood as a peripheral biomarker in 15 healthy subjects before and 1.5 and 24 h after the administration of LSD (100 μg) and placebo in a randomized, double-blind, placebo-controlled, cross-over study.

Results

LSD did not alter the expression of the HTR2A or EGR1-3 genes 1.5 and 24 h after administration compared with placebo.

Conclusion

No changes were observed in the gene expression of LSD’s primary target receptor gene or genes that are implicated in its downstream effects. Remaining unclear is whether chronic LSD administration alters gene expression in humans.

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Research Summary of 'A Single Dose of LSD Does Not Alter Gene Expression of the Serotonin 2A Receptor Gene (HTR2A) or Early Growth Response Genes (EGR1-3) in Healthy Subjects'

Editorial

βBlossom's Take

This is a useful negative study because it trims back an easy mechanistic story, a single LSD dose does not produce detectable peripheral transcriptional changes in HTR2A or EGR1-3. That does not rule out central or post-transcriptional adaptations, but it does keep claims about acute gene-expression effects appropriately narrow.

Introduction

LSD has regained interest for psychiatric research and clinical applications, yet several pharmacological effects remain incompletely understood. One notable phenomenon is the rapid development of tolerance to LSD's psychological and physiological effects with repeated dosing; early human and animal work implicates adaptations at the serotonin 5-HT2A receptor as a likely mechanism. Preclinical studies also report that acute LSD increases expression of immediate early genes such as EGR1 and EGR2 in rodent cortex via 5-HT2A receptor stimulation, and repeated dosing can reduce 5-HT2A receptor binding in frontal cortex. Liechti and colleagues set out to examine whether a single oral dose of LSD alters transcription of the 5-HT2A receptor gene (HTR2A) and early growth response genes (EGR1-3) in humans. Because direct measurement of brain gene expression in healthy people is not feasible, the investigators used peripheral whole blood mRNA as a cautious biomarker for central transcriptional responses. Their hypothesis was that LSD would acutely alter HTR2A expression and increase EGR1 and EGR2 expression in humans in a manner analogous to rodent findings.

Methods

The study used a randomised, double-blind, placebo-controlled, crossover design with two balanced experimental sessions and washout periods of at least 7 days. LSD (100 µg oral capsule) and matched placebo were each administered at 9:00 AM in standardised hospital-room sessions; participants remained supervised for the first 12 h and were monitored overnight. Although 24 healthy volunteers (12 men, 12 women) took part in the trial overall, gene expression measurements were obtained from a subset of 15 participants (7 men, 8 women; mean age 28.5 ± 5.8 years; mean weight 68 ± 8 kg; mean BMI 22.0 ± 2.0 kg/m2). Inclusion and exclusion criteria required physical and mental health, limited lifetime illicit drug exposure, and other standard protections; only two of the 15 gene-expression participants had used a hallucinogen once previously. Peripheral blood was collected into PAXgene tubes before drug administration (baseline) and at 1.5 and 24 h post-dosing. The 1.5 h time point was chosen to coincide with the expected plasma peak of LSD and the 24 h time point because partial tolerance has been documented by then in prior human work. RNA extraction followed standardised procedures with quality control (A260/A280 > 1.9; RQI > 7). Reverse transcription and quantitative real-time PCR (qPCR) were performed for HTR2A and EGR1-3, along with six candidate reference genes (ACTB, GAPDH, ALAS1, RPL13A, PPIA, RRN18S). The two least stable reference genes (GAPDH, PPIA) were excluded and normalisation used ACTB, ALAS1, RPL13A, and RRN18S. PCR runs were performed in triplicate, PCR efficiency estimated with LinRegPCR, and normalisation conducted with qBasePlus software. Plasma LSD concentrations were sampled at multiple time points up to 24 h and measured by LC–MS/MS (lower limit of quantification 0.05 ng/ml); detailed pharmacokinetic parameters were reported elsewhere. For statistical analysis, baseline gene expression values were set to 1 and post-dose values expressed as fold-change from baseline. Paired t-tests compared LSD versus placebo at each time point, and repeated-measures ANOVAs tested effects of time (0, 1.5, 24 h), with sex added as a between-subjects factor to evaluate moderation. Analyses were also standardised to mean age, body weight, and peak plasma concentration of LSD. The significance threshold was p < 0.05 and no correction for multiple comparisons was applied.

Results

Three 24 h samples had insufficient RNA and were excluded from the gene-expression analyses. Overall, neither HTR2A nor EGR1, EGR2, or EGR3 mRNA levels in whole blood changed after administration of 100 µg LSD compared with placebo at 1.5 or 24 h. The repeated-measures ANOVAs showed no significant time effects for gene expression following LSD or placebo. Reported statistics were: HTR2A (LSD: F2,24 = 0.02, P = 1.0; placebo: F2,26 = 1.24, P = 0.3), EGR1 (LSD: F2,24 = 1.14, P = 0.3; placebo: F2,26 = 1.9, P = 0.2), EGR2 (LSD: F2,24 = 1.20, P = 0.3; placebo: F2,26 = 2.67, P = 0.09), and EGR3 (LSD: F2,24 = 1.17, P = 0.2; placebo: F2,24 = 0.08, P = 0.9). Sex did not moderate the effects, and standardising the data for age, body weight, or peak plasma LSD concentration produced similar null findings. The authors also note elsewhere in the trial that participants reported subjective effects that tracked plasma LSD levels and that no acute pharmacological tolerance was evident within 12–24 h after a single dose.

Discussion

Liechti and colleagues interpret the principal finding as an absence of acute transcriptional changes in HTR2A and EGR1-3 in peripheral blood following a single 100 µg dose of LSD in healthy volunteers. The lack of an effect on HTR2A mRNA aligns with prior animal work that did not find acute changes in HTR2A gene expression in rat brain regions, but the investigators caution that receptor availability can change without altered gene transcription — for example through receptor internalisation or other post-transcriptional mechanisms. Preclinical studies reporting decreased 5-HT2A receptor binding after repeated LSD administration were cited as potentially reflecting such non-transcriptional adaptations. The null results for EGR1 and EGR2 contrast with rodent studies showing rapid, cortex-localised increases in those immediate early genes after LSD. The authors emphasise the key methodological difference that the animal studies measured brain tissue while the present work assessed blood cells; consequently, it remains possible that LSD induces transient central transcriptional responses that are not detectable peripherally. The investigators also highlight that no evidence of acute pharmacological tolerance was observed in the participants within 12–24 h, consistent with subjective effects tracking plasma concentrations and with other single-dose human data. Several limitations acknowledged by the study team temper the conclusions. Only a single, moderate dose was tested and the sample size for gene-expression analyses was relatively small. Sampling was limited to 1.5 and 24 h post-dose, so transient changes occurring between these time points could have been missed; rodent increases in EGR2, for example, have been observed up to about 5 h. Finally, peripheral blood is an imperfect surrogate for brain transcriptional activity, and adaptations relevant to tolerance or downstream signalling may be brain-specific. The authors therefore conclude that repeated-dose and more extensive temporal sampling studies, ideally with direct central measures where possible, are needed to determine whether LSD alters gene expression in humans after chronic administration.

Conclusion

A single acute oral dose of 100 µg LSD did not change the peripheral blood expression of the HTR2A gene or the early growth response genes EGR1-3 in healthy subjects at 1.5 or 24 h after administration. The findings indicate that this single-dose regimen did not produce detectable peripheral transcriptional markers of neuroadaptation, but they do not exclude central or repeated-dose effects that were not assessed in this study.

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RESULTS

The statistical analyses were performed using Statistica 12 software (StatSoft, Tulsa, OK, United States). Baseline gene expression values before drug administration were set to 1, and changes after 1.5 and 24 h are expressed as fold changes from baseline. Differences between LSD and placebo at the corresponding time points were then analyzed using paired t-tests. All comparisons were also made with data standardized to the mean age, body weight, and peak plasma concentrations of LSD. The criterion for significance was p < 0.05 without correction for multiple comparisons. Additionally, to test for changes in gene expression over time after administration of LSD or placebo, repeated measures analyses of variance (ANOVAs) were conducted with time (0, 1.5, and 24 h) as within-subject factor followed by Tukey post hoc test. To assess potential moderating effects by sex, sex was added as additional betweensubjects factor to the ANOVAs.

CONCLUSION

The key finding of the present study was that acute LSD administration did not alter the expression of the HTR2A and EGR1-3 genes in humans using peripheral blood cells as peripheral biomarker possibly reflecting central gene expression. The lack of an acute effect of LSD on HTR2A gene expression in humans is consistent with a study in rats that reported no changes in HTR2A gene expression in different brain areas. However, 5-HT 2A receptor availability may also be altered independently of HTR2A gene expression (e.g., by receptor internalization or moderation of its activity). Several studies in ratsreported a decrease in 5-HT 2A receptor binding in the prefrontal cortex or consistent trend effectsafter repeated LSD administration. Unknown, however, is whether lower binding also occurs after single-dose administration. The present findings of no changes in EGR1 and EGR2 gene expression in human blood samples after acute LSD administration contrast with preclinical findings. Specifically, LSD rapidly increased EGR1 and EGR2 expression in the cortex in ratsand mice. We expected similar rapid increases in EGR1 and EGR2 expression in humans. Importantly, however, we evaluated gene expression in human blood samples, whereas the animal studies evaluated gene expression in brain tissue. Thus, it is possible that LSD alters gene expression in the brain and not in blood. Tolerance to repeated LSD administration reportedly begins with the second daily dose of LSD, and complete tolerance develops within 3-4 days of repeated LSD administration in humans according to older studies) that need to be replicated. In the present study, we found no evidence of acute pharmacological tolerance within 12 h of acute LSD administration at a dose of 100 µg as documented in detail elsewhere. Similarly, no acute tolerance was observed after single-dose administration of 200 µg LSD in humans within 24 h. Thus, after one dose of LSD, subjective effects of LSD were self-reported by the participants as long as LSD was present in plasma, and the subjective effects did not decline more rapidly than the plasma concentrations of LSD. This is consistent with the view that LSD directly activates 5-HT 2A receptors to produce its mind-altering effects as long as it is present in the effect compartment (i.e., the brain) and assuming largely similar plasma and effect compartment kinetics. The finding of no acute tolerance in the participants in the present studyalso indicates that no FIGURE 1 | Lysergic acid diethylamide did not alter gene expression. The levels of expression of the 5-HT 2A receptor gene (HTR2A) and early growth response genes (EGR1, EGR2, and EGR3) were determined before and 1.5 and 24 h after administration of 100 µg LSD or placebo. The data are expressed as the mean ± SEM of mRNA expression levels relative to reference genes with stable expression. The respective differences in fold-changes from baseline are show in Table. relevant counterregulatory neuroadaptations occurred or were evident with the first 12-24 h after LSD administration. A recent study showed that LSD dissociates very slowly from the 5-HT 2A receptor, and the authors proposed that the high potency and long effect duration of LSD could be linked to a unique receptor interaction. However, the LSD concentration-effect relationshipshows that the presence of LSD in the body sufficiently accounted for the duration of its subjective effects. Doubling the LSD dose resulted in prolongation of the effect by approximately 3 h, consistent with its half-life of approximately 3 h. In contrast to the pharmacokinetic-pharmacodynamic relationship of LSD, other psychoactive substances, such as 3,4-methylenedioxymethamphetamine (MDMA), exhibit very marked acute pharmacological tolerance, with a rapid decline of subjective and physiological effects of MDMA within 4 h despite continuously high plasma levels and a relatively long half-life of 8 h.

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