Herring body

Herring bodies are very large swellings in the axons of the neurosecretory neurons that innervate the posterior pituitary gland. They are named after Percy Theodore Herring (1872-1967), who first observed them from histological studies of the pituitary gland that he conducted at The University of Edinburgh. Herring published his findings in the first volume of the ‘’Quarterly Journal of Experimental Physiology’’, whose principal editor, Edward Albert Sharpey-Schafer held the Chair of Physiology at the University.

In Herring’s words ‘’the posterior lobe is found to contain small hyaline bodies. Highly refractive when unstained.’’ He noted that sometimes they have a distinctly granular appearance, and speculated that they were involved in secretion, and that they might contain the physiologically active principle of the posterior lobe.

We now know that there are two "physiologically active principles" in the posterior pituitary – the hormones oxytocin and vasopressin]]. These hormones are stored in neurosecretory granules, and are secreted from the many nerve endings and smaller axonal swellings that arise from the axons that innervate the posterior pituitary gland. When viewed under the electron microscope, the Herring bodies stand out as occasional, exceptionally large aconal swellings that contain very large numbers of neurosecretory vesicles. However, the Herring bodies are not a site of secretion of these vesicles. Rather, the Herring bodies are involved in the disposal of aged neurosecretory vesicles.

When newly formed vesicles first arrive at the pituitary gland, they are first targeted to the many small neurosecretory endings from which they can be readily released. Secretion can also occur from the larger axonal swellings, but these stores are less available for secretion and accordingly seem to represent a reserve store . Neurohypophysial axons often terminate as Herring bodies , but these”end bulbs” lack the ultrastructural characteristics of release sites – in particular, they are typically engulfed by glial processes and do not directly contact the basal lamina lining the perivascular space