The comparative biology of neuromelanin and lipofuscin in the human brain.

Neuromelanin and lipofuscin are two pigments produced within the human brain that, until recently, were considered inert cellular waste products of little interest to neuroscience. Recent research has increased our understanding of the nature and interactions of these pigments with their cellular environment and suggests that these pigments may, indeed, influence cellular function. The physical appearance and distribution of the pigments within the human brain differ, but both accumulate in the aging brain and the pigments share some structural features. Lipofuscin accumulation has been implicated in postmitotic cell aging, while neuromelanin is suggested to function as an iron-regulatory molecule with possible protective functions within the cells which produce this pigment. This review presents comparative aspects of the biology of neuromelanin and lipofuscin, as well as a discussion of their hypothesized functions in brain and their possible roles in aging and neurodegenerative disease.

Investigation of the lipid component of neuromelanin.

OBJECTIVE: Neuromelanin (NM) is different to other melanins in that its ultrastructure includes a lipid component. The objectives of this study were to identify and quantify lipids associated with NM. RESULTS: Quantification of the lipid component associated with the pigment on electron micrographs demonstrated that this component comprises 35% of the NM granule volume in the normal brain. The irregular ultrastructural appearance of the NM granules was quite different to the round regular boundary of melanin granules. Using reversed phase high performance liquid chromatography (HPLC) coupled with atmospheric pressure chemical ionization (APCI) mass spectrometry we demonstrated that the isoprenoid dolichol accounted for approximately 12% of total NM pigment mass. Low levels of other lipids were detectable (cholesterol, ubiquinone-10 and alpha-tocopherol) and account for <0.05% of NM lipid, in contrast to cholesterol accounting for 35% of total brain lipids. CONCLUSION: Unlike other melanins, a substantial proportion of NM volume is comprised of lipid and the major type of lipid associated with NM granules is the isoprenoid dolichol.

Evidence for specific phases in the development of human neuromelanin.

Neuromelanin is a dark-coloured pigment which forms in the dopamine neurons of the human midbrain. Here we describe the age-related development and regulation of neuromelanin within these dopamine neurons. 10 microm sections from formalin-fixed midbrain from 29 people spanning the ages of 24 weeks to 95 years old were either stained with a basic Nissl substance stain (0.5% cresyl violet), or processed unstained. After locating the substantia nigra using the stained sections, digital photos were taken of individual ventral substantia nigra neurons in the unstained sections, and the cellular area occupied by pigment, and optical density were measured using computer software. These measurements demonstrated three developmental phases. Neuromelanin was not present at birth and initiation of pigmentation began at approximately 3 years of age, followed by a period of increasing pigment granule number and increasing pigment granule colouration until age 20. In middle and later life the colour of the pigment granules continued to darken but was not associated with any substantial growth in pigment volume. The identification of three phases and changes in the rate of neuromelanin production over time suggests the regulation of neuromelanin production and turnover, possibly through enzymatic processes.

Evidence for specific phases in the development of human neuromelanin.

Neuromelanin is a dark-coloured pigment which forms in the dopamine neurons of the human midbrain. The age-related development and regulation of neuromelanin within these dopamine neurons has not been previously described. Optical density and area measurements of unstained neuromelanin in ventral substantia nigra neurons from 29 people spanning the ages of 24 weeks to 95 years old, demonstrated three developmental phases. Neuromelanin was not present at birth and initiation of pigmentation began at approximately 3 years of age, followed by a period of increasing pigment granule number and increasing pigment granule colouration until age 20. In middle and later life the colour of the pigment granules continued to darken but was not associated with any substantial growth in pigment volume. The identification of three phases and changes in the rate of neuromelanin production over time suggests the regulation of neuromelanin production and turnover, possibly through enzymatic processes.

Neuromelanin in human dopamine neurons: comparison with peripheral melanins and relevance to Parkinson's disease.

Neuromelanin (NM) is a dark polymer pigment produced in specific populations of catecholaminergic neurons in the brain. It appears in greatest quantities in the human brain, in lesser amounts in some other non-human primates, but is absent from the brain in many lower species. Interest in this pigment has seen a resurgence in recent years because of a hypothesised link between neuromelanin and the especial vulnerability of neuromelanin-containing neurons to cell death in Parkinson's disease (PD). Little is known regarding the biology of neuromelanin. As neuromelanin appears to have characteristics in common with the better studied peripheral melanin pigments this review compares what is known about neuromelanin with melanins found in other body tissues. Unlike peripheral melanins, which are produced in specialised cells called melanocytes and may be transferred to other cell types, neuromelanin granules are believed to be stored in the cell in which they are produced. Neuromelanin granules display a unique, more heterogeneous appearance compared with peripheral melanins. Unlike melanin, neuromelanin is traditionally thought to result from a non-enzymatic synthesis pathway with no known pathway for neuromelanin catabolism. More recent data, however, is indicative of some regulation of neuromelanin synthesis and turnover. By analogy with peripheral melanins, neuromelanin may function in vivo to attenuate the effects of damaging stimuli. Among several possible mechanisms suggested, the ability of neuromelanin to interact with transition metals, especially iron, and to mediate intracellular oxidative mechanisms has received particular attention. Recent data from neuromelanin in the Parkinson's disease brain suggests that this proposed function may be compromised, thus rendering pigmented neurons vulnerable to oxidative damage in this disorder.