Video-enhanced technique for detecting neurophysin, enkephalin, and somatostatin immunoreactivity in ultrathin sections of cat median eminence.

A freeze-drying technique using epoxy-embedded ultrathin serial sections permits critical comparisons of neuropeptides in small fibers and varicosities of the nervous system by video-enhanced, light microscopic immunofluorescence. The desirability of the method was documented by data showing: retention of radioimmunoassayable somatostatin in freeze-substituted blocks of tissue as compared to its loss in tissue dehydrated in an alcohol series; feasibility of OsO4 vapor fixation of freeze-dried tissue and compatibility with neuropeptide immunocytochemistry, and utility of a silicon-intensified-tube video camera for recording low levels of fluorescence from ultrathin sections. Ultrathin serial sections, 150 nm thick, from the inner zone of freeze-dried median eminence of the cat revealed three populations of axons containing various combinations of neurophysin immunoreactivity and enkephalin immunoreactivity. Some elements contained neurophysin immunoreactivity alone, some contained both neurophysin immunoreactivity and enkephalin immunoreactivity, and a few elements contained enkephalin immunoreactivity alone. The adjacent external zone of the median eminence contained immunoreactivity for all three substances, but the structures in this region were too small to permit demonstration of coexistence in 150 nm thick sections.

Long-term storage and regular repeated use of diluted antisera in glass staining jars for increased sensitivity, reproducibility, and convenience of single- and two-color light microscopic immunocytochemistry.

A procedure is described for the dilution and storage of antisera in glass staining jars into which whole slides are immersed for incubation during light microscopic neuropeptide immunocytochemistry. Diluted antisera, stored at 4 degrees C and continuously reused, were found to be stable for long periods of time (to date over 3 years), and consistently yielded high quality staining in both single- and two-color immunoperoxidase staining. We found this procedure to be more convenient than conventional incubation procedures, allowing the more rapid processing of large numbers of slides and reducing the loss of slides due to technical errors. The consistency and reproducibility of day to day staining were also improved. The immersion of whole slides into the antisera permitted the use of long incubation times (up to 7 days) without the sections drying out, which in many cases substantially enhanced the sensitivity of the staining obtained. A procedure for two-color immunoperoxidase staining is described using diaminobenzidine for a brown color and alpha-naphthol/pyronin for a red/purple color. We found the alpha-naphthol/pyronin reaction superior to the more commonly used 4-chlornaphthol reaction as a second color. The two-color staining was found useful not only for demonstrating nerve cell bodies stained different colors, but also for staining nerve terminals one color that are around and contacting nerve cell bodies stained another color.

Use of serial 1-2 micrometer paraffin sections in neuropeptide immunocytochemistry for sequential analysis of different substances contained within the same neurons.

The preparation of serial 1.0, 1.5, or 2.0 micrometer paraffin sections is described. The sections are cut from paraffin blocks with surface areas of up to 5 mm x 10 mm, using glass knives and a Jung Autocut microtome. Large numbers of serial sections can easily be prepared and stained by immunohistochemistry for sequential analysis. These sections are useful for demonstrating several different substances contained within the same neurons or for detailed topographical comparison of neurons that contain different substances within the same nucleus.