Analysis of the UV-Induced Melanogenesis and Growth Arrest of Human Melanocytes

Cultured human melanocytes derived from different skin types responded to frequent treatment with ultraviolet (UV) light with increased melanin synthesis, decreased proliferation, and morphologic signs of aging. These effects were augmented by increased frequency of irradiation with 15.5 mJ/cm² UV light. Stimulation of melanogenesis by UV light involved an increase in tyrosinase activity, without any change in the amounts of either tyrosinase or tyrosinase-related protein (TRP)-1, and a decrease in the amount of TRP-2, as determined by Western blot analysis. These results are different from the mechanisms by which other melanogenic agents, such as cholera toxin and isobutyl methylxanthine, stimulated melanogenesis, whereby the amounts of tyrosinase, TRP-1 and TRP-2 were increased. The decrease in the amount of TRP-2 might be significant in that it might alter the properties of the newly synthesized melanin. The UV irradiation protocol that was followed blocked melanocytes in G₂-M phase of the cell cycle without compromising cellular viability. Following three rounds of UV irradiation, melanocytes could recover from the growth arrest and resume proliferation. Treatment with 0.1 μM α-melanocyte stimulating hormone (α-MSH) postirradiation enhanced the melanogenic effect of UV light and stimulated the melanocytes to proliferate. The effects of α-MSH on the UV induced responses and their implications on photocarcinogenesis are being further investigated. Analyzing the mechanisms by which UV light exposure affects normal melanocytes might lead to a better understanding of how these cells undergo malignant transformation, and why individuals with different skin types differ in their susceptibility to skin cancers.     

Assessing the ecological risk from secondary salinity: A framework addressing questions of scale and threshold responses

Abstract Assessment of the ecological risk posed to native vegetation from the development of shallow and saline water tables is considered an urgent task in southern Australia. Ecological risk can be defined as the product of the likelihood of an ecological effect and the consequences of that effect. At present, the likelihood of the development of a shallow water table is determined by hydrological modelling at the catchment scale, and this in itself is often equated to ecological risk. In contrast, the ecological consequences of secondary salinity are generally investigated at the patch scale. Translating ecological likelihood and the ecological consequences of risk across these scales has proved problematic, both conceptually and quantitatively. Here we argue that the consideration of ecological risk within the context of the patch‐ or catchment‐scale is based upon human perceptions of spatial units, rather than the ecological scales at which various processes determine vegetation dynamics. By focusing on the processes that determine vegetation dynamics, and the dimensions of these processes, both spatial and temporal scales can be built into conceptual frameworks that aim to understand vegetation change, such as frameworks of alternative stable states. We present an alternative conceptual framework of the ecological risk from secondary salinity based around using the rates of processes, such as salt accumulation in the soil or the frequency of waterlogging, at the scales at which these processes occur. This framework also integrates concepts of vegetation states and transitions between meta‐stable states and alternative stable states.     

Proliferation and Propagation of Human Melanocytes in Vitro Are Affected by Donor Age and Anatomical Site

We report the effects of two factors, donor age and anatomical site, on the proliferation and melanization of human melanocytes (MC) derived from (1) neonatal foreskins, (2) adult foreskins, or (3) adult breast or arm skin. Two different growth media have been used for this purpose. Medium I supports the long-term proliferation of neonatal MC, and medium II supports the growth of both neonatal and adult MC. We found that neonatal foreskin MC proliferated equally well in both media for more than 12 passages. However, adult MC behaved differently in the two growth media. In very early passages (passages 1-5), all three types of MC proliferated well and reached comparable final cell densities in medium I, but adult foreskin MC proliferated at a higher rate than neonatal or adult non-foreskin MC in medium II. The non-foreskin adult MC had the least proliferative rate in medium II. Unlike neonatal MC, both adult foreskin and non-foreskin MC underwent a drastic reduction in their proliferative rate after only a few (9-10) passages in culture. While the three types of MC differed in their proliferative rates, they responded similarly to melanogenic stimulation by cholera toxin (CT) and isobutyl methylxanthine (IBMX). These results demonstrate that the proliferation of human MC in standard culture media is affected by the donor age and the anatomical site from which these cells are derived. We conclude that human MC are heterogeneous, and caution must be used in extrapolating the results of studies on MC derived from different anatomical sites or age groups.