Insect cuticle or exoskeleton is a complex extracellular matrix formed primarily from structural polysaccharide chitin and protein, and it plays a critical role in protecting them from various environmental stresses and pathogenic infection. Despite of limited composition, insect cuticle has remarkably diverse mechanical properties, ranging from soft and flexible to hard and rigid. My research has been focusing on functional importance of the genes involved in chitin metabolism and cuticle tanning (sclerotization and pigmentation) to comprehensively understand the genetic, enzymatic as well as molecular mechanism underlying differentiation, development and formation of insect cuticular extracellular matrices.

Insect cuticle is a first physical barrier to protect their body from multifarious environments. Cuticle tanning (sclerotization and pigmentation) is a complex process involves hydroxylation of tyrosine to 3,4-dihydroxyphenylalanine (DOPA), decarboxylation of DOPA to dopamine, N-acylation of dopamine to N-acetyldopamine (NADA) or N-β-alanyldopamine (NBAD), oxidation of NADA and NBAD to their corresponding quinones, and reactions between the quinones or quinone derivatives with cuticular proteins (CPs) resulting in protein cross-linking. N-acetyltransferase (NAT) catalyzes the conversion of dopamine to NADA whose covalent-linkage of CPs is correlated with colorless cuticle (β-sclerotization). In this study, we analyzed functions of TcNAT1 on cuticle tanning of adult Tribolium castaneum by RNAi. Injection of dsRNA for TcNAT1 (dsTcNAT1) had no affect on animal development and growth. However, some of the resulting adults (~70%) showed split elytra that could not cover their abdomen, resulting in improper folding of their hindwings. Interestingly, body color of the mature adults was darker than that of control dsTcVer-treated adults because probably due to the buildup of abnormally high levels of dopamine, which is used for dopamine eumelanin pigment synthesis (black pigment). On elytra and hindwings of these adults, darker pigments were observed around the sensory bristles located at the intervein regions, suggesting that NADA mediated β-sclerotization is occurred in these regions. Similarly, darker pigment was evident at veins of the hindwings of TcNAT1-deficient adults. These results suggest that TcNAT1 plays important roles in cuticle tanning of T. castaneum adult. To characterize enzymatic properties of TcNAT1, furthermore, recombinant TcNAT1 protein expressed in E. coli was purified by utilizing Ni-NTA affinity column chromatography. This work was supported by NRF (NRF-2012R1A2A1A01006467).

Insect cuticle/exoskeleton is a first physical barrier to protect their body from multifarious environments such as desiccation, natural enemies and entomopathogenic microorganisms. Cuticle tanning (sclerotization and pigmentation) is a vital procedure for generating suitable cuticle depending on body region by sclerotization and pigmentation in insects. Insect cuticle tanning is a complex process involves hydroxylation of tyrosine to 3,4-dihydroxyphenylalanine (DOPA), decarboxylation of DOPA to dopamine, N-acylation of dopamine to N-acetyldopamine (NADA) or N-β-alanyldopamine (NBAD), oxidation of NADA and NBAD to their corresponding quinones, and reactions between the quinones or quinone derivatives with cuticle protein (CP) side chains resulting in protein cross-linking. One type of pigmentation (quinone tanning) is associated with the covalent linkage of CPs to the ring component of NBAD. In contrast, linkage of CPs to the side chain of NADA (b-sclerotization) is correlated with colorless cuticle. N-acetyltransferase (NAT) catalyzes the conversion of dopamine to N-acetyl dopamine (NADA) in cuticle tanning pathway. In this study, we studied function of TcNAT1 on adult cuticle tanning by double stranded-RNA (dsRNA) mediated gene silencing. Injection of dsTcNAT1 had no affect on animal development, growth and molting such as larva to larva, larva to pupa and pupa to adult. However, some of the resulting adults (~70%) showed split elytra that could not cover their abdomen, resulting in improper folding of their hindwings. Interestingly, body color of the mature adults (older than 3 days) was darker than that of control dsTcVer treated adults because probably due to the buildup of abnormally high levels of dopamine, which is used for dopamine eumelanin pigment synthesis (black pigment) and dopamine quinone-mediated protein crosslinking. On elytra and hindwings of these adults, darker pigments were observed around the sensory bristles that are located in the intervein regions, suggesting that NADA mediated b-sclerotization is occurred at these regions. Similarly, darker pigment was evident at veins of the hindwings of the dsTcNAT1-mature adults. These results suggest that TcNAT1 have important roles in sclerotization and pigmentation of adult body and wings (elytron and hindwing). This work was supported by NRF (NRF-2012R1A2A1A01006467).