Melanocyte development in the mouse tail epidermis requires the Adamts9 metalloproteinase.

The mouse tail has an important role in the study of melanogenesis, because mouse tail skin can be used to model human skin pigmentation. To better understand the development of melanocytes in the mouse tail, we cloned two dominant ENU-generated mutations of the Adamts9 gene, Und3 and Und4, which cause an unpigmented ring of epidermis in the middle of the tail, but do not alter pigmentation in the rest of the mouse. Adamts9 encodes a widely expressed zinc metalloprotease with thrombospondin type 1 repeats with few known substrates. Melanocytes are lost in the Adamts9 mutant tail epidermis at a relatively late stage of development, around E18.5. Studies of our Adamts9 conditional allele suggest that there is a melanocyte cell-autonomous requirement for Adamts9. In addition, we used a proteomics approach, TAILS N-terminomics, to identify new Adamts9 candidate substrates in the extracellular matrix of the skin. The tail phenotype of Adamts9 mutants is strikingly similar to the unpigmented trunk belt in Adamts20 mutants, which suggests a particular requirement for Adamts family activity at certain positions along the anterior-posterior axis.

Microfluidic Production and Application of Lipid Nanoparticles for Nucleic Acid Transfection.

Lipid nanoparticles (LNPs) are established in the biopharmaceutical industry for efficient encapsulation and cytosolic delivery of nucleic acids for potential therapeutics, with several formulations in clinical trials. The advantages of LNPs can also be applied in basic research and discovery with a microfluidic method of preparation now commercially available that allows preparations to be scaled down to quantities appropriate for cell culture. These preparations conserve expensive nucleic acids while maintaining the particle characteristics that have made LNPs successful in later stages of genetic medicine development. Additionally, this method and the resulting LNPs are seamlessly scalable to quantities appropriate for in vivo models and development of nucleic acid therapeutics.The present work describes the methodology for preparing LNPs loaded with siRNA, mRNA or plasmids using a commercially available microfluidic instrument and an accompanying transfection kit. Guidelines for application to cultured cells in a well-plate format are also provided.

The Human Dental Pulp Proteome and N-Terminome: Levering the Unexplored Potential of Semitryptic Peptides Enriched by TAILS to Identify Missing Proteins in the Human Proteome Project in Underexplored Tissues.

An underexplored yet widespread feature of the human proteome is the proteolytic proteoforms of proteins. We used terminal amine isotopic labeling of substrates (TAILS), a high-content N-terminal positional proteomics technique, for in-depth characterization of the human dental pulp proteome from its N-terminome and to provide data for the Chromosome-centric Human Proteome Project (C-HPP). Dental pulp is a unique connective tissue maintaining tooth sensation and structure by supporting a single cell layer of odontoblasts that synthesize mineralization-competent dentine extracellular matrix. Therefore, we posited pulp to be a rich source of unique tissue-specific proteins and hence an abundant source of "missing" proteins as defined by neXtProt. From the identified 4332 proteins (false discovery rate (FDR) ≤ 0.7%), 21 528 unique peptides (FDR ≤ 1.0%) and 9079 unique N-termini, we analyzed N-terminal methionine excision, co- and posttranslational Nα-acetylation, protein maturation, and proteolytic processing. Apart from 227 candidate alternative translation initiation sites, most identified N-termini (78%) represented proteolytic processing and mechanism-informative internal neo-N-termini, confirming a pervasive amount of proteolytic-processing generated proteoforms in vivo. Furthermore, we identified 17 missing protein candidates for the C-HPP, highlighting the importance of using (i) less studied human specimens and (ii) orthogonal proteomic approaches such as TAILS to map the human proteome. The mass spectrometry raw data and metadata have been deposited to ProteomeXchange with the PXD identifier .

Adam10 haploinsufficiency causes freckle-like macules in Hairless mice.

The Hairless nuclear receptor co-repressor is required for hair follicle regeneration during the hair cycle. The classical Hairless(Hr) /Hairless(Hr) mouse mutant loses all hair between 2 and 3 weeks of age. As the mice age, their trunk skin develops epidermal pigmentation, a feature of human skin which is not found in normal haired mice. In this report, we present a new, dominant mouse mutation, Pied, which arose within a colony of Hairless(Hr) /Hairless(Hr) mice and causes freckle-like macules on the skin. The Pied macules require Hairless(Hr) homozygosity to form and are composed of localized clusters of epidermal melanocytes. Through linkage analysis, we find that the Pied mutation is a 1914 base pair loss-of-function deletion in the Adam10 zinc metalloprotease gene. The pathways that specifically maintain long-term pigmentation patterns in adults are not well understood. We have identified Adam10 as an inhibitor of melanocyte expansion in adult skin.

Differential patterns of apoptosis in response to aging in Drosophila.

Several lines of evidence suggest that programmed cell death may play a role in the aging process and the age-related functional declines of multicellular organisms. To pave the way for the use of Drosophila to rigorously test this hypothesis in a genetic model organism, this work examines the pattern of apoptosis in the adult fly during aging. The analysis across the lifespan of caspase activity and DNA fragmentation shows that apoptosis occurs in adult flies at all ages and that it is linked to physiological age. The results establish that under normal conditions, fly aging is coupled with a lifelong gradual increase of apoptosis within muscle cells and an activation of apoptosis in fat cells of old flies. The nervous system does not show signs of apoptosis. These time- and tissue-specific changes indicate that aging influences the levels and the nature of the cells that commit to apoptosis. The comparison with the apoptotic response to starvation and oxidative stresses strongly suggests that the lifelong increase in flight and leg muscles results from the accumulation of oxidative damage associated with aging. This finding presents an attractive mechanism to account for the decline of locomotor functions and muscle loss in the elderly and opens the way for the genetic analysis of sarcopenia in Drosophila.