Colling S B, Stanford I M, Traub R D, Jefferys J G
Neuroscience Unit, Department of Physiology, The Medical School, University of Birmingham, Edgbaston, Birmingham B15 2TT, United Kingdom.
J Neurophysiol. 1998 Jul;80(1):155-61. doi: 10.1152/jn.1998.80.1.155.
Gamma oscillations (approximately 40 Hz) were induced in transverse hippocampal slices by tetanic stimulation of CA1 and/or subiculum. Tetanic stimulation of each site elicited population gamma oscillations in the surrounding tissue <400 micro(m) away. Stimulation of CA1 alone could evoke activity at both CA1 and subiculum. Subicular stimulation, however, did not transmit to CA1. When the rostral end of CA1 was stimulated, gamma oscillations transmitted across <1.5 mm of silent CA1 before reappearing in the subiculum. Tetanic stimulation of CA1 increased [K+]o to 8.2 +/- 1.5 mM (mean +/- SE). The location of the peak increase corresponded to the site of local gamma generation. Silent areas of CA1 experienced smaller [K+]o increases, to 4.9 +/- 0.7 mM. The subiculum, which generated gamma, remained at the baseline 3.0 mM. Although fluctuations in [K+]o may have an impact on the generation of gamma rhythms, they are not necessary for them. Gamma oscillations had similar frequencies in CA1 and subiculum (40.4 +/- 2.9 and 43.9 +/- 3.1 Hz, respectively). When present in both, the oscillations typically were phase locked with the subiculum lagging by 5.4 +/- 1.8 ms. When both CA1 and subiculum were stimulated the lag decreased by 28%. These delays approximate those expected for the conduction velocity of axons between the two regions, here estimated at 0.52 +/- 0.07 m/s. Transmission of gamma oscillations from CA1 to subiculum was blocked by the focal addition of the alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid-receptor antagonist, 6-nitro-7-sulfamoylbenzo[f]quinoxaline-2,3-dione, to the subiculum. Oscillations induced in CA1 by local tetanic stimulation were blocked by focal application of the gamma-aminobutyric acid-A (GABAA) receptor antagonist, bicuculline, to CA1. Focal application of bicuculline to the subiculum blocked gamma due to subicular stimulation but not that due to CA1 stimulation. Bath-applied bicuculline disrupted subicular gamma evoked by subicular stimulation and led to a transient period of epileptiform responses before completely blocking responses. The further addition of the GABAB receptor antagonist, CGP 55845A, reversed this block, restoring the epileptic discharges evoked by tetanic stimulation. This suggests that the subiculum differs from hippocampal CA3 and neocortex, in having a powerful GABAB receptor-dependent mechanism to prevent epileptic discharges. The subiculum generates gamma rhythms both in response to local stimulation and to gamma rhythms evoked in CA1. Subicular gamma differs from that in CA1 in the presence of population spike doublets rather than singlets on many cycles. In both areas, generation of gamma by local stimulation depends on GABAA receptors, suggesting that the subiculum shares the interneuronal network mechanism we proposed for CA1.
通过对CA1区和/或下托进行强直刺激,在横向海马切片中诱导出γ振荡(约40Hz)。对每个部位的强直刺激在周围<400微米的组织中引发群体γ振荡。单独刺激CA1可在CA1区和下托区均诱发活动。然而,下托区的刺激并未传导至CA1区。当刺激CA1区的前端时,γ振荡在跨越<1.5毫米的静息CA1区后在下托区再次出现。对CA1区的强直刺激使细胞外钾离子浓度([K+]o)升高至8.2±1.5毫摩尔/升(平均值±标准误)。升高峰值的位置与局部γ振荡产生的部位相对应。CA1区的静息区域[K+]o升高幅度较小,为4.9±0.7毫摩尔/升。产生γ振荡的下托区[K+]o保持在基线水平3.0毫摩尔/升。尽管[K+]o的波动可能对γ节律的产生有影响,但并非γ节律产生所必需。CA1区和下托区的γ振荡频率相似(分别为40.4±2.9赫兹和43.9±3.1赫兹)。当两者都存在γ振荡时,振荡通常呈锁相状态,下托区滞后5.4±1.8毫秒。当同时刺激CA1区和下托区时,滞后时间减少28%。这些延迟时间与两个区域之间轴突传导速度预期值相近,此处估计为0.52±0.07米/秒。通过在下托区局部添加α-氨基-3-羟基-5-甲基-4-异恶唑丙酸受体拮抗剂6-硝基-7-氨磺酰基苯并[f]喹喔啉-2,3-二酮,可阻断γ振荡从CA1区向下托区的传导。通过在CAI区局部应用γ-氨基丁酸-A(GABAA)受体拮抗剂荷包牡丹碱,可阻断局部强直刺激在CA1区诱导的振荡。在下托区局部应用荷包牡丹碱可阻断下托区刺激引起但非CA1区刺激引起的γ振荡。浴用荷包牡丹碱可破坏下托区刺激诱发的下托区γ振荡,并在完全阻断反应之前导致一段短暂的癫痫样反应期。进一步添加GABAB受体拮抗剂CGP 55845A可逆转这种阻断,恢复强直刺激诱发的癫痫放电。这表明下托区与海马CA3区和新皮层不同,具有强大的依赖GABAB受体的机制来防止癫痫放电。下托区在对局部刺激以及对CA1区诱发的γ节律做出反应时均可产生γ节律。下托区的γ振荡与CA1区的不同之处在于,在许多周期中存在群体峰电位双峰而非单峰。在两个区域中,局部刺激产生γ振荡均依赖GABAA受体,这表明下托区具有我们为CA1区提出的中间神经元网络机制。
