Zhang L, Schmidt R E, Yan Q, Snider W D
Department of Neurology, Washington University Medical School, St. Louis, Missouri 63110.
J Neurosci. 1994 Sep;14(9):5187-201. doi: 10.1523/JNEUROSCI.14-09-05187.1994.
The functions of neurotrophins in relation to axon growth and branching during development of the nervous system are unknown. In order to address this question, we have investigated the influences of systemically administered mouse nerve growth factor (mNGF) and human recombinant neurotrophin-3 (hrNT-3) on dorsal root axon growth in the spinal cord of embryonic rats. As anticipated, mNGF has a marked influence on growth of dorsal root axons. In mNGF-treated animals, dorsal root axons in the developing dorsal funiculi and axon collaterals in developing gray matter are substantially longer than those of age-matched controls. Furthermore, growth cones of some dorsal root axons have more than twice the surface area of controls. These effects of NGF are highly selective. Dorsal root axons that occupy a lateral position in white matter and that normally give off collaterals to superficial dorsal horn are prominently affected. Axons that run medially in dorsal columns and that give off collaterals to laminae III and IV and the ventral horn are not demonstrably influenced by treatment with exogenous mNGF. In contrast to the striking effects of mNGF on dorsal root axon growth, the influences of hrNT-3 were considerably more complex. Administration of hrNT-3 increased the mean soma area of DRG neurons, particularly those at the larger end of the size spectrum, consistent with its hypothesized role as a growth factor for proprioceptive sensory neurons. However, in striking contrast to the actions of mNGF, hrNT-3 consistently inhibited axon collateral growth in gray matter at early developmental stages. At later stages, we could not discern a clear-cut influence of hrNT-3 on dorsal root axon growth and branching. We conclude that the ability of mNGF to stimulate axon growth in both white and gray matter is consistent with the idea that mNGF regulates the developing axonal projections of DRG neurons in vivo. In contrast, systemically administered hrNT-3 inhibits the axon collateralizations of DRG neurons in gray matter at early developmental stages. We hypothesize that this inhibitory effect may be related to disruption of a chemotropic gradient of NT-3, or to the widespread expression of the NT-3 receptor trkC, on non-neuronal cells.
神经营养因子在神经系统发育过程中与轴突生长和分支的关系尚不清楚。为了解决这个问题,我们研究了全身给药的小鼠神经生长因子(mNGF)和人重组神经营养因子-3(hrNT-3)对胚胎大鼠脊髓背根轴突生长的影响。正如预期的那样,mNGF对背根轴突的生长有显著影响。在接受mNGF治疗的动物中,发育中的背侧索中的背根轴突和发育中的灰质中的轴突侧支明显比年龄匹配的对照组更长。此外,一些背根轴突的生长锥表面积是对照组的两倍多。NGF的这些作用具有高度选择性。在白质中占据外侧位置且通常向浅表背角发出侧支的背根轴突受到显著影响。在内侧背柱中运行并向板层III和IV以及腹角发出侧支的轴突,未显示受到外源性mNGF治疗的明显影响。与mNGF对背根轴突生长的显著影响相反,hrNT-3的影响要复杂得多。给予hrNT-3增加了背根神经节(DRG)神经元的平均胞体面积,特别是那些处于大小谱较大端的神经元,这与其作为本体感觉神经元生长因子的假设作用一致。然而,与mNGF的作用形成鲜明对比的是,hrNT-3在发育早期始终抑制灰质中的轴突侧支生长。在后期,我们无法辨别hrNT-3对背根轴突生长和分支的明确影响。我们得出结论,mNGF刺激白质和灰质中轴突生长的能力与mNGF在体内调节DRG神经元发育中的轴突投射的观点一致。相比之下,全身给药的hrNT-3在发育早期抑制DRG神经元在灰质中的轴突侧支形成。我们假设这种抑制作用可能与NT-3化学趋向性梯度的破坏有关,或者与NT-3受体trkC在非神经元细胞上的广泛表达有关。