About Skin Whitening Agent
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The Hunt for Natural Skin Whitening Agents
Skin whitening products are commercially available for cosmetic purposes in order to obtain a lighter skin appearance. They are also utilized for clinical treatment of pigmentary disorders such as melasma or postinflammatory hyperpigmentation. Whitening agents act at various levels of melanin production in the skin. Many of them are known as competitive inhibitors of tyrosinase, the key enzyme in melanogenesis. Others inhibit the maturation of this enzyme or the transport of pigment granules (melanosomes) from melanocytes to surrounding keratinocytes. In this review we present an overview of (natural) whitening products that may decrease skin pigmentation by their interference with the pigmentary processes.
Keywords: whitening, tyrosinase inhibitors, natural agents, cosmetics
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1. Introduction
In the skin, melanocytes are situated on the basal layer which separates dermis and epidermis. One melanocyte is surrounded by approximately 36 keratinocytes. Together, they form the so-called epidermal melanin unit. The melanin produced and stored inside the melanocyte in the melanosomal compartment is transported via dendrites to the overlaying keratinocytes. The melanin pigment is a polymer produced inside the melanosomes and synthesised from the amino acid l-tyrosine that is converted by the enzyme tyrosinase to dopaquinone [1]. This reaction continues spontaneously via dopachrome to the monomeric indolic precursors (5,6-dihydroxyindole and 5,6-dihydroxyindole 2-carboxylic acid) of the black-brown pigment eumelanin. However, some other enzymes, like the tyrosinase related proteins (TRP-1 and dopachrome tautomerase (TRP-2) may also play an important role in melanogenesis in vivo. Upon reaction with cysteine, dopaquinone forms 2- or 5-S-cysteinyldopa that generates the benzothiazine precursors of the red/yellow pheomelanin polymer. In general, a mixed type of pheo- and eumelanin polymer is produced and deposited onto the melanosomal matrix proteins. Considering the many colour variations that can be seen in the skin and hair, one may expect that the composition of the mixed melanins is regulated in many different ways. However, altered production of cutaneous melanin may cause considerable problems of esthetic nature, especially in hyperpigmentary conditions, like melasma, postinflammatory hyperpigmentation, freckles or lentigines. But also depigmenting conditions, like vitiligo, have high impact on the quality of life of the patients.
In the Western culture it is still considered desirable to obtain a (bronze) tan. Despite warnings about the consequences of excessive sun or UV exposure, the artificial tanning business has expanded strongly in the last decades. In the Eastern world, however, a centuries long tradition exists whereby a light complexion is regarded as equivalent to youth and beauty. Development of preparations for bleaching hyperpigmented lesions or to safely achieve overall whitening is one of the challenges for cosmetic industry. In recent years, the interest in skin whitening has grown tremendously.
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2. Targeting Tyrosinase as the Key Enzyme of Melanogenesis
One of the most obvious cellular targets for depigmenting agents is the enzyme tyrosinase. The scientific literature on tyrosinase inhibition shows that a large majority of the work has been conducted since 2000 and has mostly been devoted to the search for new depigmenting agents. Notably, many of these studies deal with tyrosinase inhibitors from natural sources and are mostly of Asian origin (see Tables 1 and and2).2). However, early pioneering work in the field has been performed much earlier using 4-hydroxyanisole. This compound could serve as an alternative substrate for tyrosinase causing depigmentation both in vivo and in vitro [2,3]. Since this and various other substituted phenolic compound can generate potentially toxic quinone products they were used in various studies aimed at the induction of toxicity mediated by tyrosinase in melanoma cells [4,5].
Table 1.
Table 1.
Compounds selected as tyrosinase inhibitors by extraction from natural sources and the (possible) isolation and characterization of the active ingredients.
Table 2.
Table 2.
New whitening agents from natural sources and their mode of action as tyrosinase inhibitor (TI), inhibitor of pigment synthesis (PI) or by other mechanisms. Azelaic acid, Kojic acid, Arbutin and Aloesin are often used as positive skin whitening agents. ...
Considerable interest in tyrosinase inhibitors exists also in the food industry because the activity of this enzyme is responsible for the browning of fruit and vegetables. Cysteine or ascorbic acid can be used to prevent the enzymatic browning of fruit and vegetables by binding the o-dopaquinone intermediates. More recently also 4-hexylresorcinol has been utilized for this purpose [6–9]. Since safety considerations are very strict in food industry, the search for new, natural tyrosinase inhibitors without negative side effects is of utmost importance in this field of research.
Work on synthetic and natural tyrosinase inhibitors has been recently reviewed in several papers [7,9,10]. The tyrosinase inhibitors can be classified as competitive, uncompetitive, mixed type and non-competitive inhibitors [10]. The nature of tyrosinase inhibition can be disclosed by measuring enzyme inhibition kinetics using Lineweaver-Burk plots with varying concentrations of l-DOPA as the substrate. This can be seen on example of polyphenol extracts from acerola (West Indian cherry) or a chalcone derivative isolated from Morus nigra (black mulberry) which has been described in recent work of Hanamura et al. and Zhang et al. [11,12]. Knowledge of the type of inhibition may be important in order to achieve better skin lightening effects since combined treatments may result in synergistic effects. This has been shown in case of the competitive tyrosinase inhibitor, arbutin and the noncompetitive inhibitor, aloesin [9,13].
A 2009 paper by Chang states that a large majority of tyrosinase inhibitors show reversible inhibition [10]. In irreversible inhibition, covalent binding with the enzyme may cause its inactivation by altering the active site of the enzyme and/or by conformational changes to the protein molecule. Irreversible inhibition may also occur via the so-called suicide inhibition mechanism as described in the model by Land et al. [14]. Also, two 8-hydroxy isoflavones isolated from soygerm koji showed suicide inhibition of tyrosinase and have been tested with promising results in an in vivo assay with 60 volunteers [10]. In Table 1 we summarize the large number of studies using tyrosinase inhibitors from natural sources that have appeared, mostly in the last decade. In many of the investigations, the active ingredients from extracts of various species have been isolated and identified. In case the mode of tyrosinase inhibition was established, a comparison with IC50 values of well known inhibitors such as kojic acid and arbutin was often made. In some of the studies specific side groups (with substitutions to C4, C5 or C8 position) of recorcinols isolated from the breadfruit (Artocarpus incisus) or from a ‘bitter root’ (Sophora flavescens) proved of great importance to their inhibitory potential [15,16]. In some cases modifications to the natural compounds were made, e.g., the deglycosylation of stilbene compounds by cellulase treatment of the Veratrum patulum extract resulted in improved tyrosinase inhibition [17]. Thus, exact knowledge on enzyme inhibition mechanisms is helpful for designing new whitening products based on targeting the key enzyme of melanogenesis, tyrosinase. Although tyrosinase plays a major role in melanin synthesis, one should realize that the regulation of skin pigmentation exists at various levels and therefore, different modes of interference are possible. There are indications that combined approaches could be more successful than targeting tyrosinase only.
TI; tyrosinase inhibition, (c) competitive mode (nc) non competitive mode of inhibition. SB; Streptomyces bikiniensis [47]. MMS; molecular modeling studies on TI. SAR; structure activity relationship. PI; pigment inhibition.
The Hunt for Natural Skin Whitening Agents
Skin whitening products are commercially available for cosmetic purposes in order to obtain a lighter skin appearance. They are also utilized for clinical treatment of pigmentary disorders such as melasma or postinflammatory hyperpigmentation. Whitening agents act at various levels of melanin production in the skin. Many of them are known as competitive inhibitors of tyrosinase, the key enzyme in melanogenesis. Others inhibit the maturation of this enzyme or the transport of pigment granules (melanosomes) from melanocytes to surrounding keratinocytes. In this review we present an overview of (natural) whitening products that may decrease skin pigmentation by their interference with the pigmentary processes.
Keywords: whitening, tyrosinase inhibitors, natural agents, cosmetics
Go to:
1. Introduction
In the skin, melanocytes are situated on the basal layer which separates dermis and epidermis. One melanocyte is surrounded by approximately 36 keratinocytes. Together, they form the so-called epidermal melanin unit. The melanin produced and stored inside the melanocyte in the melanosomal compartment is transported via dendrites to the overlaying keratinocytes. The melanin pigment is a polymer produced inside the melanosomes and synthesised from the amino acid l-tyrosine that is converted by the enzyme tyrosinase to dopaquinone [1]. This reaction continues spontaneously via dopachrome to the monomeric indolic precursors (5,6-dihydroxyindole and 5,6-dihydroxyindole 2-carboxylic acid) of the black-brown pigment eumelanin. However, some other enzymes, like the tyrosinase related proteins (TRP-1 and dopachrome tautomerase (TRP-2) may also play an important role in melanogenesis in vivo. Upon reaction with cysteine, dopaquinone forms 2- or 5-S-cysteinyldopa that generates the benzothiazine precursors of the red/yellow pheomelanin polymer. In general, a mixed type of pheo- and eumelanin polymer is produced and deposited onto the melanosomal matrix proteins. Considering the many colour variations that can be seen in the skin and hair, one may expect that the composition of the mixed melanins is regulated in many different ways. However, altered production of cutaneous melanin may cause considerable problems of esthetic nature, especially in hyperpigmentary conditions, like melasma, postinflammatory hyperpigmentation, freckles or lentigines. But also depigmenting conditions, like vitiligo, have high impact on the quality of life of the patients.
In the Western culture it is still considered desirable to obtain a (bronze) tan. Despite warnings about the consequences of excessive sun or UV exposure, the artificial tanning business has expanded strongly in the last decades. In the Eastern world, however, a centuries long tradition exists whereby a light complexion is regarded as equivalent to youth and beauty. Development of preparations for bleaching hyperpigmented lesions or to safely achieve overall whitening is one of the challenges for cosmetic industry. In recent years, the interest in skin whitening has grown tremendously.
Go to:
2. Targeting Tyrosinase as the Key Enzyme of Melanogenesis
One of the most obvious cellular targets for depigmenting agents is the enzyme tyrosinase. The scientific literature on tyrosinase inhibition shows that a large majority of the work has been conducted since 2000 and has mostly been devoted to the search for new depigmenting agents. Notably, many of these studies deal with tyrosinase inhibitors from natural sources and are mostly of Asian origin (see Tables 1 and and2).2). However, early pioneering work in the field has been performed much earlier using 4-hydroxyanisole. This compound could serve as an alternative substrate for tyrosinase causing depigmentation both in vivo and in vitro [2,3]. Since this and various other substituted phenolic compound can generate potentially toxic quinone products they were used in various studies aimed at the induction of toxicity mediated by tyrosinase in melanoma cells [4,5].
Table 1.
Table 1.
Compounds selected as tyrosinase inhibitors by extraction from natural sources and the (possible) isolation and characterization of the active ingredients.
Table 2.
Table 2.
New whitening agents from natural sources and their mode of action as tyrosinase inhibitor (TI), inhibitor of pigment synthesis (PI) or by other mechanisms. Azelaic acid, Kojic acid, Arbutin and Aloesin are often used as positive skin whitening agents. ...
Considerable interest in tyrosinase inhibitors exists also in the food industry because the activity of this enzyme is responsible for the browning of fruit and vegetables. Cysteine or ascorbic acid can be used to prevent the enzymatic browning of fruit and vegetables by binding the o-dopaquinone intermediates. More recently also 4-hexylresorcinol has been utilized for this purpose [6–9]. Since safety considerations are very strict in food industry, the search for new, natural tyrosinase inhibitors without negative side effects is of utmost importance in this field of research.
Work on synthetic and natural tyrosinase inhibitors has been recently reviewed in several papers [7,9,10]. The tyrosinase inhibitors can be classified as competitive, uncompetitive, mixed type and non-competitive inhibitors [10]. The nature of tyrosinase inhibition can be disclosed by measuring enzyme inhibition kinetics using Lineweaver-Burk plots with varying concentrations of l-DOPA as the substrate. This can be seen on example of polyphenol extracts from acerola (West Indian cherry) or a chalcone derivative isolated from Morus nigra (black mulberry) which has been described in recent work of Hanamura et al. and Zhang et al. [11,12]. Knowledge of the type of inhibition may be important in order to achieve better skin lightening effects since combined treatments may result in synergistic effects. This has been shown in case of the competitive tyrosinase inhibitor, arbutin and the noncompetitive inhibitor, aloesin [9,13].
A 2009 paper by Chang states that a large majority of tyrosinase inhibitors show reversible inhibition [10]. In irreversible inhibition, covalent binding with the enzyme may cause its inactivation by altering the active site of the enzyme and/or by conformational changes to the protein molecule. Irreversible inhibition may also occur via the so-called suicide inhibition mechanism as described in the model by Land et al. [14]. Also, two 8-hydroxy isoflavones isolated from soygerm koji showed suicide inhibition of tyrosinase and have been tested with promising results in an in vivo assay with 60 volunteers [10]. In Table 1 we summarize the large number of studies using tyrosinase inhibitors from natural sources that have appeared, mostly in the last decade. In many of the investigations, the active ingredients from extracts of various species have been isolated and identified. In case the mode of tyrosinase inhibition was established, a comparison with IC50 values of well known inhibitors such as kojic acid and arbutin was often made. In some of the studies specific side groups (with substitutions to C4, C5 or C8 position) of recorcinols isolated from the breadfruit (Artocarpus incisus) or from a ‘bitter root’ (Sophora flavescens) proved of great importance to their inhibitory potential [15,16]. In some cases modifications to the natural compounds were made, e.g., the deglycosylation of stilbene compounds by cellulase treatment of the Veratrum patulum extract resulted in improved tyrosinase inhibition [17]. Thus, exact knowledge on enzyme inhibition mechanisms is helpful for designing new whitening products based on targeting the key enzyme of melanogenesis, tyrosinase. Although tyrosinase plays a major role in melanin synthesis, one should realize that the regulation of skin pigmentation exists at various levels and therefore, different modes of interference are possible. There are indications that combined approaches could be more successful than targeting tyrosinase only.
TI; tyrosinase inhibition, (c) competitive mode (nc) non competitive mode of inhibition. SB; Streptomyces bikiniensis [47]. MMS; molecular modeling studies on TI. SAR; structure activity relationship. PI; pigment inhibition.
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