Stereotaxic Microinjection of Viral Vectors Expressing Cre Recombinase to Study the Role of Target Genes in Cocaine Conditioned Place Preference

Podsumowanie

This article describes how to microinject viral vectors into mouse brain and then test in a conditioned place preference paradigm that includes an acquisition, extinction and reinstatement phase.

Streszczenie

Microinjecting recombinant adenoassociated viral (rAAV) vectors expressing Cre recombinase into distinct mouse brain regions to selectively knockout genes of interest allows for enhanced temporally- and regionally-specific control of gene deletion, compared to existing methods. While conditional deletion can also be achieved by mating mice that express Cre recombinase under the control of specific gene promoters with mice carrying a floxed gene, stereotaxic microinjection allows for targeting of discrete brain areas at experimenter-determined time points of interest. In the context of cocaine conditioned place preference, and other cocaine behavioral paradigms such as self-administration or psychomotor sensitization that can involve withdrawal, extinction and/or reinstatement phases, this technique is particularly useful in exploring the unique contribution of target genes to these distinct phases of behavioral models of cocaine-induced plasticity. Specifically, this technique allows for selective ablation of target genes during discrete phases of a behavior to test their contribution to the behavior across time. Ultimately, this understanding allows for more targeted therapeutics that are best able to address the most potent risk factors that present themselves during each phase of addictive behavior.

Wprowadzenie

Cocaine is a highly reinforcing psychostimulant. Following repeated exposure, several molecular and cellular adaptations occur in reward-relevant brain circuitry that are believed to result in compulsive drug-seeking behavior, prompting high rates of relapse which pose a serious clinical problem ¹. Cocaine exerts these long-lasting behavioral effects by regulating gene expression. To study the adaptations that arise from chronic cocaine use, preclinical rodent models have been used extensively. One such model is the conditioned place preference (CPP) paradigm. This model involves the development of a learned association between a previously neutral environment and the rewarding properties of cocaine. After several pairings of cocaine with a particular chamber, animals are allowed to freely explore the cocaine-paired and non-cocaine-paired environments and if they prefer the drug-paired compartment, they are said to have acquired a cocaine-induced place preference. Moreover, following an extinction training period, this paradigm can be used to study context-specific reinstatement of cocaine-seeking behavior.

Compared to other behavioral models of addictive-like behavior, such as psychomotor sensitization, which is used to study long-term cocaine-induced behavioral and molecular plasticity ^2,3 and self-administration (SA), that is thought to more accurately mimic addictive-like behavior found in humans, the CPP paradigm is a simple procedure to study cocaine contextual learning ⁴. CPP protocols can be conveniently extended to include extinction and reinstatement phases, similarly to SA, which allow for investigation of the mechanisms underlying drug craving and relapse ^5-7 and which are believed to recapitulate aspects of what occurs in human drug-seeking behavior and drug- and cue-induced relapse ^8-10.

One mechanism that underlies the cocaine-induced behavioral plasticity that is characteristic of each of the distinct phases of CPP, including acquisition, extinction, and reinstatement, is activation of unique signatures of gene expression within different brain regions. To directly test which genes within reward-relevant brain regions mediate cocaine-induced behavioral changes, it is useful to be able to manipulate them selectively in a regionally-specific manner. One way of achieving this is to microinject recombinant adenoassociated viral (rAAV) vectors that express Cre recombinase using stereotaxic surgery, into distinct brain areas of mice that have target genes flanked by LoxP sites (floxed mice). This method allows for very precise temporal and regional control over when and where genes are ablated, in both dividing and non-dividing neurons, without inducing immune responses ^11-13. This level of control represents an important advantage over traditional Cre-LoxP technology of breeding floxed mice with mice expressing Cre recombinase under the control of an endogenous gene promoter, in that the timing and distribution of gene deletion can be more tightly regulated. Additionally, viral vector-mediated gene knockout circumvents potential developmental compensatory effects that may occur using traditional knockout strategies.

In addition to cocaine CPP, which is described here, microinjection of rAAV-Cre into the brain of floxed mice to assess the role of specific genes can be applied ubiquitously to behavioral paradigms that involve separate phases, including self-administration and psychomotor sensitization. For example, our laboratory has utilized the rAAV-Cre technology to study the role of Ca_v1.2 L-type Ca²⁺ channels in cocaine psychomotor sensitization ¹⁴. Specifically, rAAV-Cre was microinjected into the nucleus accumbens (NAc) of mice with the gene encoding Ca_v1.2 floxed, to demonstrate that Ca_v1.2 acting in this region mediates the expression phase of psychomotor sensitization ^14,15. However, the rAAV-Cre strategy cannot be used if mice with a floxed gene of interest do not exist, as was our experience when assessing the role of Ca_v1.3 L-type Ca²⁺ channels in psychomotor sensitization. Hence, a limitation of using rAAV-Cre presents itself if conditional mice do not exist for a particular gene of interest. However, rAAVs that express siRNA can be used to knockdown target genes, as we have done to examine the role of Ca_v1.3 channels ^14,15.

Microinjecting rAAV-Cre into discrete brain regions of floxed mice and then testing them in the CPP paradigm allows for investigation into the specific genes that mediate the various phases of addictive-like behavior and where they are acting. Use of this paradigm has aided in our understanding of how repeated cocaine administration in essence hijacks the brains reward circuitry causing maladaptive changes in molecular signal transduction pathways and gene expression that lead to the addicted state ^1,16,17.

Protokół

All procedures are conducted in accordance with the Weill Cornell Medical College Institutional Animal Care and Use Committee rules.

1. Preparation and Setup for Stereotaxic Delivery of Viral Vectors

1. If an instrument, sterile swab, or hand wearing sterile glove is contaminated by coming into contact with a non-sterile surface, discard or re-sterilize the instrument using a hot bead sterilizer, discard the swab or change to new sterile gloves.
2. Place a mouse cage with bedding on a heat block to warm for post-operative recovery.
3. Set up electric razor for shaving head and ethanol and iodine to sterilize the scalp.
4. Wipe down ear bars and mouth hold of the stereotax with 70% ethanol.
5. Using a 5 μl Hamilton syringe, draw up 5 μl of viral vector (1 x 10⁶ viral particles/μl) and set up in syringe holder on stereotax.
6. Microwave heating pad or turn electric pad on and place on stereotax. Cover with a clean absorbent pad to reduce the risk of burns. Monitor mouse body temperature (between 97-99.5 °F) frequently throughout procedure.
7. Inject mouse (weighing between 22-35 g) with a mixture of ketamine (100 mg/kg) and xylazine (20 mg/kg). Once a mouse is anesthetized, pinch tail tip to check the mouse's reflexes and note any movement or response to ensure that the mouse is adequately anesthetized.
8. Shave head between ears and eyes.
9. Clean shaved head with alternating ethanol and iodine sterile cotton applicators.
10. Transfer mouse to heated pad on stereotax.

2. Stereotaxic Microinjection of Viral Vectors

1. Wear sterile gloves throughout the surgery. If gloves are contaminated at any point by touching non-sterile surfaces, change gloves.
2. Zero tooth bar and ear bar scales.
3. Set teeth in tooth bar.
4. Screw in muzzle. If wiggling or whisker movement is noted at any time, administer an i.p. booster dose (~0.05 cc) of a mixture of ketamine (100 mg/kg) and xylazine (20 mg/kg).
5. Screw in ear bars.
6. Lubricate eyes with PuraLube.
7. Cut open scalp to just behind ears with a scalpel.
8. Place bulldog clips on the corners of the scalp to peel the skin away from skull. Bregma and lambda should be easily visible.
9. Make sure suture from bregma to lambda is aligned straight. If the suture is crooked readjust positioning of the head.
10. Check to make sure all settings on the stereotax are zeroed.
11. Put needle tip in place at bregma.
12. Measure all coordinates for both bregma and lambda. This includes dorsal/ventral, medial/lateral and anterior/posterior coordinates.
13. Adjust the head until the ventral coordinates for bregma and lambda are within 0.02 mm of each other.
14. Once aligned, from bregma go medially out to the medial/lateral (M/L) coordinates. Make sure the left and right sides are aligned within 0.02 mm of each other.
15. Re-center needle tip on bregma and from there move in the anterior/posterior (A/P) direction to the desired anterior/posterior coordinate.
16. If necessary, angle needle in one direction and make sure the stereotax is locked. Go out to the left M/L coordinate (+/- 1.52)
17. Measure the ventral position of the top of the skull to use as a reference after the borehole is drilled.
18. Drill a borehole using a sterile drill bit at the desired coordinate. Check that the needle can enter uninterrupted through the skull.
19. Lower the needle to the desired ventral coordinate.
20. Once the coordinate is reached, dip 0.015 mm below for ~10 sec to create a small pocket for the viral vector.
21. Inject the desired volume of viral vector at a rate of ~0.1 μl/min. Wait 3 min for viral vector to diffuse completely. Raise the needle tip 0.015 mm and wait an additional 2 min.
22. Dip the needle (if doing angled injections) in the opposite direction. Again, record the ventral position as a reference for the top of the skull.
23. Repeat the same steps as on the first side to inject viral vector on the opposite side (if doing bilateral injections).
24. Apply bone wax to both holes to seal them using the wooden end of a sterile cotton applicator tip.
25. Suture the scalp.
26. Apply nerve block to the wounded area.
27. Remove mouse from stereotax and place in warmed cage on heat block to recover for 45 min.
28. Monitor for signs of pain including: decreased overall activity or restlessness, decreased food and water consumption or increased vocalization. Buprenorphine (0.05 - 0.2 mg/kg) can be administered twice daily for a week if necessary for pain. Acceptable alternatives include: meperidine (20-60 mg/kg), pentazocine (10 mg/kg), nalbuphine (4-8 mg/kg).

3. Conditioned Place Preference: Acquisition, Extinction, and Reinstatement

1. Place mice into the central chamber of a three-chamber place preference apparatus (Med Associates Inc., St. Albans, VT, USA) for a 60 sec habituation period with guillotine doors closed.
2. After habituation, open guillotine doors and allow mice free exploration of all 3 chambers for 1,200 sec, with time spent in each chamber being recorded using MedPC IV software (Med Associates, Inc.).
3. Assign mice to conditioning chambers based on their performance during the pre-test. Using a biased design, pair drug administration during the subsequent 3 days with the compartment that was least-preferred during the baseline pre-test.
4. During the next 3 conditioning days, inject mice with cocaine (10 mg/kg; i.p.) during the morning session and confine them in their assigned chamber for 1,200 sec immediately following the injection. Return mice to their home cages after the session. After 4 hr, inject mice with saline (0.01 ml/g body weight) and confine them to the opposite chamber for the 1,200 sec afternoon session.
5. To test for acquisition, place mice in the central chamber with guillotine doors closed for a 60 sec habituation period. Open guillotine doors and allow free exploration for 1,200 sec, with time spent in all chambers recorded by MedPC IV software (Med Associates, Inc.). Calculate preference by subtracting the amount of time spent in the saline-paired chamber from the amount of time spent in the cocaine-paired chamber.
6. To extinguish the place preference, expose mice to two 20 min sessions of free exploration daily in the same apparatus, separated by at least 2 hr, beginning 24 hr following the test for acquisition. Time spent in all chambers should again be recorded and the magnitude of the initial CPP should be compared with that of each extinction session.
7. Determine whether mice have extinguished the drug-induced preference by assessing whether preference for a particular chamber across two consecutive extinction days is significantly lower compared to the acquisition preference score.
8. Reinstate mice with a priming dose of cocaine (5 or 10 mg/kg; i.p.) and re-expose to the apparatus allowing free exploration and record the time spent in each compartment.
9. Administer Euthasol euthanasia solution (150 mg/kg). Transcardially perfuse mice with 4% paraformaldehyde (PFA) and perform a histological examination to validate correct microinjection placement.

Wyniki

CPP

After performing CPP on microinjected mice, one should verify that the cohort of control-injected (rAAV-GFP) mice have normally acquired preference for the drug-paired chamber (Figure 1A, 1B). Mice are considered to have acquired preference for a particular chamber when cocaine preference (time spent in the cocaine-paired chamber minus time spent in the saline-paired chamber) is significantly higher compared to baseline preference score (Figure 1B, A vs. B). ...

Dyskusje

Regionally- and temporally-specific gene ablation via stereotaxic microinjection of viral vectors combined with CPP that includes extinction and reinstatement phases allows for investigation of the specific contributions of genes to three distinct phases of addictive-like behavior. While conditional knockout that is achieved utilizing the traditional Cre-LoxP system provides for spatio-temporally restricted gene ablation, stereotaxically microinjecting Cre-recombinase into discrete brain areas of floxed mice allows for e...

Materiały

Name	Company	Catalog Number	Comments
Conditioned place preference activity chambers	Med Associates, Inc., St. Albans, VT, USA	MED-CPP-MS
Stereotaxic alignment system for mouse	David Kopf Instruments, Tujunga, CA, USA	model 900
Hamilton syringes	Hamilton Company, Reno, Nevada, USA	7634-01
rAAV2-Cre-GFP	Vector BioLabs, Philadelphia, PA, USA	7016
rAAV2-GFP	Vector BioLabs, Philadelphia, PA, USA	7004