Genetic Regulation of Melanocyte Differentiation

Melanocytes originate from the neural crest in vertebrates and migrate to the body surface where they differentiate into functional cells. Genes involved in melanocyte differentiation can be classified into two groups. One of them consists of the functional genes that control proteins specific to the function of the melanocyte. As the representative gene of this category, albino (c) locus in the mouse is considered to control tyrosinase, the key enzyme in melanogenesis. cDNA for mouse tyrosinase has been cloned and sequenced. The cDNA can be used to detect tyrosinase mRNA synthesized during melanocyte differentiation. On the other hand, genes such as brown (b) or pink-eyed dilution (p) have been assumed to control melanosome proteins. The other category consists of genes that regulate the expression of these functional genes directly or indirectly. In the mouse, so-called white-spotting genes and genes of the agouti series are considered to fall into this category. Based on the fact that mutations at the white-spotting loci result in the absence of melanocytes in a particular area of skin, it is assumed that some of these loci control the factors that promote either differentiation or migration of melanoblasts and are candidates for the classic regulator genes Genes at the agouti (a) locus in the mouse determine the type of melanin synthesized in hair follicle melanocytes, that is eumelanin or pheomelanin. An interesting feature of this locus is that the site of gene action is not within the melanocytes but in the cells surrounding them. The results of our study indicate that the gene product of the a-locus interacts with α-MSH at the α-MSH receptor site, regulates the cellular cAMP level via a signal transduction system and, in turn, determines the type of melanin synthesized in the cells.     

Efficient Isolation of Novel Mouse Genes Differentially Expressed in Early Postimplantation Embryos

Most genes with regulatory functions in embryogenesis are expressed in highly specific patterns, suggesting that expression patterns can serve as criteria to define potential candidates fur developmentally relevant genes. To isolate such genes, we selected and partially sequenced 80 cDNA clones from a 10.5-day mouse embryo library. Forty-one clones that represented novel mouse genes were analyzed for expression in embryos of the same stage by whole-mount in situ hybridization. A high proportion (24%) of these genes, including a homologue of the Drosophila Delta gene, were expressed in specific spatially restricted patterns, suggesting that selection based on expression patterns is a useful strategy to isolate novel genes that may play pivotal roles in mammalian development.     

An expressed sequence tag database of T-cell-enriched activated chicken splenocytes: sequence analysis of 5251 clones

The cDNA and gene sequences of many mammalian cytokines and their receptors are known. However, corresponding information on avian cytokines is limited due to the lack of cross-species activity at the functional level or strong homology at the molecular level. To improve the efficiency of identifying cytokines and novel chicken genes, a directionally cloned cDNA library from T-cell-enriched activated chicken splenocytes was constructed, and the partial sequence of 5251 clones was obtained. Sequence clustering indicates that 2357 (42%) of the clones are present as a single copy, and 2961 are distinct clones, demonstrating the high level of complexity of this library. Comparisons of the sequence data with known DNA sequences in GenBank indicate that approximately 25% of the clones match known chicken genes, 39% have similarity to known genes in other species, and 11% had no match to any sequence in the database. Several previously uncharacterized chicken cytokines and their receptors were present in our library. This collection provides a useful database for cataloging genes expressed in T cells and a valuable resource for future investigations of gene expression in avian immunology. A chicken EST Web site (http://udgenome. ags.udel. edu/chickest/chick.htm) has been created to provide access to the data, and a set of unique sequences has been deposited with GenBank (Accession Nos. AI979741-AI982511). Our new Web site (http://www. chickest.udel.edu) will be active as of March 3, 2000, and will also provide keyword-searching capabilities for BLASTX and BLASTN hits of all our clones.     

Gene structure of chick cartilage chondroitin sulfate proteoglycan (aggrecan) core protein

Large aggregating chondroitin sulfate proteoglycan (CSPG/aggrecan) is one of the major extracellular matrix components in cartilage. The core protein is also large, over 200 kDa, and modular with a distinct correspondence between protein structural domains and the encoding exons. Here we report the isolation, using chick CSPG cDNA probes and the ensuing sequencing, of genomic clones containing exons encoding the chick CSPG core protein. The 5 two globular domains, G1 and G2, are encoded by four and three exons, respectively, and the interglobular domain is encoded by a single exon. The chondroitin sulfate attachment domain is encoded by the largest exon, 3,216 bp, which is approximately 50% of the total coding sequence. Combined with the previous report (Tanaka, T., Har-el, R. Tanzer, M.L. 1988 J. Biol. Chem. 263, 15831–15835), these data reveal that the chick CSPG gene contains at least 18 exons spanning a genome which is greater than 30 kb. No evidence was obtained for multiple genes for aggrecan in the chick genome. Elucidation of the chick genomic structure allows comparison of the avian and mammalian link protein genes to the homologous portions of avian and mammalian core protein genes (hyaluronate binding domain) with respect to their origins and paths of duplication and divergence. Correspondence to: N.B. Schwartz     

Cloning and characterisation of the abundant cytoplasmic 7S RNA from mouse cells.

A cDNA library has been prepared from mouse embryo small RNAs and screened for the presence of clones complementary to the highly abundant cytoplasmic 7S RNA. One clone (pA6) was selected which hybridized exclusively with 7S RNA on a Northern blot prepared from cytoplasmic RNA run on high resolution polyacrylamide/urea gels. Sequence analysis of this clone has shown that at least 65 nucleotides at the 5' end of 7S RNA are extensively homologous with the highly repeated mouse B1 family. Heterologous hybridisations between the cloned mouse 7S sequence and RNAs prepared from rat, human and chick cells have shown that the non-B1 part of the 7S RNA molecule has been highly conserved during recent eucaryotic evolution. There are multiple copies of 7S RNA genes in the genomes of mouse, human, rat and chick cells, but substantial differences exist in copy number and genomic organisation in these organisms.     

Isolation of a large number of novel mammalian genes by a differential cDNA library screening strategy.

As part of the ongoing human and mouse genome projects, the aim of this study was to isolate novel, previously uncharacterized, genes from mouse testis. Two approaches were compared for their effectiveness in isolating novel genes: random, vs differential, complementary DNA (cDNA) cloning methods. In the differential approach, only the cDNA clones containing rare sequences (as determined by preliminary clone hybridization) are further analyzed; in the random approach, cDNA clones are isolated at random from the cDNA library. More than two hundred cDNA clones altogether were analyzed, using a PCR-mediated amplification and sequencing strategy. A comparison of these sequences to nucleic acid and protein sequence databases, revealed that 84% of the isolated rare cDNA clones represented new, previously uncharacterized mouse genes. In contrast, less than 63% of the cDNA clones isolated at random from cDNA libraries, contained novel genes. Thus, the probability of isolating new, previously uncharacterized, mammalian genes from cDNA libraries can be markedly improved by focusing efforts on clones containing rare sequences.     

Isolation of cDNA Clones for Epidermis-Specific Genes of the Ascidian Embryo

The present investigation was conducted to isolate cDNA clones that correspond to epidermis-specific genes of the ascidian embryo. When cleavage of fertilized eggs of Halocynthia roretzi is blocked by treatment with cytochalasin B and the arrested eggs are reared as one-celled embryos for about 30 hr, they develop features of differentiation of the epidermis only. Translation in vitro of poly(A)⁺ RNA from cleavage-arrested embryos and analysis of the products by two-dimensional gel electrophoresis revealed several predominant polypeptides that were not detected in a similar analysis of fertilized eggs, suggesting the appearance of epidermis-specific mRNAs in cleavage-arrested embryos. A cDNA library was constructed from arrested one-celled embryos. Differential screening of the library with a total cDNA probe from cleavage-arrested embryos and with a similar probe from fertilized eggs yielded eight different cDNA clones specific for the cleavage-arrested embryos. Northern blot analysis revealed that the mRNAs that corresponded to these cDNAs were present in normal tailbud embryos. In addition, in situ hybridization of whole-mount specimens showed that the mRNAs were restricted to the epidermal cells of tailbud embryos.     

Expression of virally transduced mouse tyrosinase in tyrosinase-negative chick embryo melanocytes in culture

A cDNA encoding mouse tyrosinase was inserted into a plasmid containing the provirus of a replication competent avian leukosis virus (ALV). A viral stock produced from the plasmid was used to infect cultured tyrosinase-negative (ca/ca) unpigmented chick embryo melanocytes. Five days after infection many cells were producing very dark discrete melanosomes.     

Isolation and characterization of variant cDNAs encoding mouse tyrosinase

Two different cDNA clones encoding mouse tyrosinase (monophenol oxygenase, E.C. 1.14.18.1) were isolated from B16 melanoma cells, and their primary structure was determined. One of the cDNAs consists of 3309 nucleotides with an open reading frame coding for a peptide of 533 amino acids. The other cDNA is approximately 1600 nucleotides long, with a shorter 3'-untranslated region and a deduced in-frame deletion of 77 amino acid residues with respect to the former clone. Neither of these clones is structurally identical to other described mouse tyrosinase cDNAs (1-3). RNA blotting analysis demonstrates that multiple tyrosinase mRNA species are not only present in B16 melanoma, but also in normal skin melanocytes.     

Genes for basement membrane proteins are coordinately expressed in differentiating F9 cells but not in normal adult murine tissues

We have obtained cDNA clones coding for the A, B1, and B2 chains of laminin by screening a cDNA library prepared from mouse EHS tumor poly(A)RNA in the lambda gt11 expression vector with polyclonal antibody against denatured laminin. These cDNA clones were used in combination with a cDNA clone coding for the alpha 1 type IV collagen chain to study the regulation of genes for these basement membrane proteins in retinoic acid-induced differentiating mouse F9 teratocarcinoma cells and in various adult murine tissues. The levels of mRNA for the laminin A, B1, and B2 chains and for the alpha 1 type IV collagen chain were increased simultaneously and reached a maximum at almost the same time during the differentiation of F9 cells, suggesting coordinate expression in these cells. The tissue levels of mRNA encoding for the basement membrane components, however, varied considerably. The highest level of the B1 chain mRNA was observed in kidney, whereas, the levels of mRNA for A and B2 chains were highest in heart. Almost the same levels of expression of the alpha 1(IV) collagen mRNA were found in kidney, lung, and heart. The results indicate that the expression of genes for the basement membrane proteins is not coordinately regulated in these tissues. It is thus possible that different subunit structures of the laminin molecule may exist in tissues.     

The molecular cloning and characterization of potential chick DM-GRASP homologs in zebrafish and mouse

A full-length zebrafish cDNA clone and a partial mouse cDNA clone similar to chick DM-GRASPwere isolated and analyzed. The nucleotide sequence of the full-length zebrafish clone shares 54% identity, and predicts 39% amino acid identity, with chick DM-GRASP. The partial mouse clone shares 76% nucleotide identity, and predicts 76% amino acid identity, with chick DM-GRASP. The predicted proteins encoded by both of these clones exhibit conserved structural domains that are characteristic of the chick protein. These features may identify them as a distinct subfamily within the immunoglobulin superfamily of cell adhesion molecules. Express of the zebrafish DM-GRASP protein is similar to chick DM-GRASP and is principally restricted to a small subset of developing sensory and motor neurons during axonogenesis. Zebrafish DM-GRASP expression was temporally regulated and limited to specific axon domains. This regional expression correlated with fasciculated axon domains. These results suggest that the zebrafish and mouse cDNA clones represent the respective fish and mammalian homologs of thick DM-GRASP. The highly selective expression of zebrafish DM-GRASP suggests that it is involved in the selective fasciculation and guidance of axons along their normal pathways. 1994 John Wiley & Sons, Inc.     

Prediction of the coding sequences of mouse homologues of FLJ genes: the complete nucleotide sequences of 110 mouse FLJ-homologous cDnas identified by screening of terminal sequences of cDNA clones randomly sampled from size-fractionated libraries.

We have been conducting a mouse cDNA project to predict protein-coding sequences of mouse KIAA-homologous genes since 2001. As an extension of this project, we also started to accumulate mouse cDNA clones homologous to the human FLJ cDNA clones which are another long cDNA resource produced in our institute. We have isolated the cDNA clones from size-fractionated cDNA libraries derived from five different mouse tissues and natural killer T-cells. Although the human FLJ cDNA clones were originally derived from human spleen libraries, one-third of their mouse homologues were obtained from the brain library. We designated these homologues "mFLJ" plus a 5-digit number and herein characterized 110 mFLJ cDNA clones. We assigned an integrity of the CDSs from the comparison of the 110 cDNA clones with the corresponding human FLJ cDNA clones. The average size of the 110 mouse cDNA sequences was 3.8 kb and that of the deduced amino acid sequences from their longest CDS in each cDNA was 663 amino acid residues. Homology and/or motif search against public databases revealed new domains and/or motifs in 26 mFLJ gene products which provide additional speculation regarding the function of FLJ genes.