Binding of mammalian brain microtubule-associated proteins (MAPs) to insect ovarian microtubules

In this study we have applied microtubule-associated proteins (MAPs) from mammalian brain to both native and reassembled insect ovarian microtubules. Such microtubules, which are normally smooth walled, become decorated with projections similar to those observed when mammalian brain MAPs are added back to assembling or assembled mammalian brain microtubules. The mammalian MAPs were also detected as components of insect microtubules when analyzed by polyacrylamide gel electrophoresis. Our observations suggest that mammalian brain MAPs have common binding sites on microtubules from two widely different sources and indicate the degree of evolutionary conservation of such sites.     

Mammalian glycosyltransferase expression allows sialoglycoprotein production by baculovirus-infected insect cells.

The baculovirus-insect cell expression system is widely used to produce recombinant mammalian glycoproteins, but the glycosylated end products are rarely authentic. This is because insect cells are typically unable to produce glycoprotein glycans containing terminal sialic acid residues. In this study, we examined the influence of two mammalian glycosyltransferases on N-glycoprotein sialylation by the baculovirus-insect cell system. This was accomplished by using a novel baculovirus vector designed to express a mammalian alpha2,6-sialyltransferase early in infection and a new insect cell line stably transformed to constitutively express a mammalian beta1,4-galactosyltransferase. Various biochemical assays showed that a foreign glycoprotein was sialylated by this virus-host combination, but not by a control virus-host combination, which lacked the mammalian glycosyltransferase genes. Thus, this study demonstrates that the baculovirus-insect cell expression system can be metabolically engineered for N-glycoprotein sialylation by the addition of two mammalian glycosyltransferase genes.     

Oxidative metabolites and genotoxic potential of mammalian and plant lignans in vitro

Certain plant lignans, e.g. secoisolariciresinol and matairesinol, are converted by the intestinal microflora to the mammalian lignans enterodiol and enterolactone, which are associated with beneficial health effects in humans. The metabolism of both mammalian and plant lignans in animals and humans is poorly understood, and most studies so far have focused on the conjugation of these diphenolic compounds. However, recent studies have demonstrated that mammalian and plant lignans are good substrates for cytochrome p450-mediated reactions, leading to numerous products of aliphatic and aromatic hydroxylation with microsomes in vitro. The current knowledge of the oxidative metabolism of food-related lignans is briefly reviewed in this paper, including published as well as unpublished data from our laboratory. Moreover, data on the genotoxic potential of the mammalian and plant lignans, determined at various endpoints in cultured mammalian cells, are included in this review.     

Evolution of sialic acid-binding proteins: molecular cloning and expression of fish siglec-4

Siglecs are the largest family of sialic acid-recognizing lectins identified so far with 11 members in the human genome. Most of these siglecs are exclusively expressed by cells of the immune system. Comparison of different mammalian species has revealed differential and complex evolutionary paths for this protein family, even within the primate lineage. To understand the evolution of siglecs, in particular the origin of this family, we investigated the occurrence of corresponding genes in bony fish. Interestingly, only unambiguous orthologs of mammalian siglec-4, a cell adhesion molecule expressed exclusively in the nervous system, could be identified in the genomes of fugu and zebrafish, whereas no obvious orthologs of the other mammalian siglecs were found. As in mammals, fish siglec-4 expression is restricted to nervous tissues as demonstrated by northern blot. Expressed as recombinant protein, fish siglec-4 binds to sialic acids with a specificity similar to the mammalian orthologs. Relatively low sequence similarities in the cytoplasmic tail as well as an additional splice variant found in fish siglec-4 suggest alternative signaling pathways compared to mammalian species. Our observations suggest that this siglec occurs at least in the nervous system of all vertebrates.     

Metabolic biotinylation of secreted and cell surface proteins from mammalian cells

Due to its strength and specificity, the interaction between avidin and biotin has been used in a variety of medical and scientific applications ranging from drug targeting to immunohistochemistry. To maximize the application of this technology in mammalian systems, we recently demonstrated the ability to metabolically biotinylate tagged proteins in mammalian cells using the endogenous biotin ligase enzymes of the mammalian cell. This technology allows site-specific biotinylation without any exogenous reagents and eliminates possible inactivation of the protein of interest by nonspecific biotinylation. Here, we report further expansion of the mammalian metabolic biotinylation technology to enable biotinylation of proteins secreted from mammalian cells and expressed on their cell surface by cosecretion with BirA, the biotin ligase of E. coli. This technique can be used to biotinylate secreted proteins for purification or targeting and also for biotinylating the surfaces of mammalian cells to facilitate their labeling and purification from other nontagged cells.     

Review of non-permeating cryoprotectants as supplements for vitrification of mammalian tissues

Vitrification of mammalian tissues is important in the areas of human assisted reproduction, animal reproduction, and regenerative medicine. Non-permeating cryoprotectants (CPAs), particularly sucrose, are increasingly used in conjunction with permeating CPAs for vitrification of mammalian tissues. Combining non-permeating and permeating CPAs was found to further improve post-thaw viability and functionalities of vitrified mammalian tissues, showing the potential applications of such tissues in various clinical and veterinary settings. With the rising demand for the use of non-permeating CPAs in vitrification of mammalian tissues, there is a strong need for a timely and comprehensive review on the supplemental effects of non-permeating CPAs toward vitrification outcomes of mammalian tissues. In this review, we first discuss the roles of non-permeating CPAs including sugars and high molecular weight polymers in vitrification. We then summarize the supplemental effects of non-permeating CPAs on viability and functionalities of mammalian embryos, and ovarian, testicular, articular cartilage, tracheal, and kidney tissues following vitrification. Lastly, challenges associated with the use of non-permeating CPAs in vitrification of mammalian tissues are briefly discussed.     

Expression of the Cytoskeletal-Associated Protein Filamin in Adult Rat Organs

Filamin is a well-characterized actin-associated protein first isolated from chicken smooth muscle. Subsequently, this polypeptide and its nonmuscle homolog actin-binding protein have been shown to be expressed in avian muscle tissue, mammalian smooth muscle, mammalian macrophages and other blood cell types, as well as several cultured cell lines. In this report, the occurrence of this polypeptide in adult mammalian organs has been investigated. Immunoblot analysis using three anti-filamin monoclonal antibodies showed that this protein was largely detected in adult rat organs that possess a substantial smooth muscle component. Furthermore, the limited expression of filamin in smooth muscle tissue was corroborated by immunohistochemical analysis. In contrast to avian systems, filamin was never found in detectable quantities in either mammalian cardiac or skeletal muscle. Quantitative immunoblot analysis demonstrated that filamin amounts roughly correlated with the abundance of the smooth muscle component of a given organ, comprising as much as 16.5% of the total SDS-extractable protein in bovine aorta. Work in avian systems and cells in culture has suggested that filamin is a rather ubiquitous cytoskeletal element. By contrast, this work demonstrates that filamin is highly restricted in its expression in mammalian organ systems, in situ.     

Development of zebrafish epidermis

Zebrafish epidermal ionocytes are analogous to mammalian kidney cells in terms of expression and function of ion transporters. In this review, we summarize current findings about the development of the zebrafish epidermis and demonstrate how the zebrafish regulate stress acclimation through induction of cell differentiation. In addition, cellular homologies between zebrafish epidermal ionocytes and mammalian kidney cells are presented to show the potential of zebrafish epidermis as an in vivo model to study the development and function of mammalian cells.     

Quantitative evaluation of mammalian skeletal muscle as a heterologous protein expression system

The production of mammalian proteins in sufficient quantity and quality for structural and functional studies is a major challenge in biology. Intrinsic limitations of yeast and bacterial expression systems preclude their use for the synthesis of a significant number of mammalian proteins. This creates the necessity of well-identified expression systems based on mammalian cells. In this paper, we demonstrate that adult mammalian skeletal muscle, transfected in vivo by electroporation with DNA plasmids, is an excellent heterologous mammalian protein expression system. By using the fluorescent protein EGFP as a model, it is shown that muscle fibers express, during the course of a few days, large amounts of authentic replicas of transgenic proteins. Yields of approximately 1mg/g of tissue were obtained, comparable to those of other expression systems. The involvement of adult mammalian cells assures an optimal environment for proper protein folding and processing. All these advantages complement a methodology that is universally accessible to biomedical investigators and simple to implement.     

BIM and other BCL-2 family proteins exhibit cross-species conservation of function between zebrafish and mammals

Here we investigate the function of zebrafish Bcl-2 family proteins and demonstrate important conservation of function across zebrafish and mammalian systems. We have isolated a zebrafish ortholog of mammalian BIM and show that it is the most toxic of the zebrafish BH3-only genes examined, sharing this characteristic with the mammalian BIM gene. The zebrafish bad gene shows a complete lack of embryonic lethality, but like mammalian BAD, its pro-apoptotic activity is regulated through phosphorylation of critical serines. We also found that the pattern of mitochondrial dysfunction observed by zebrafish BH3 domain peptides in a mammalian cytochrome c release assay recapitulates the pattern of embryonic lethality induced by the respective mRNA injections in vivo. In contrast to zebrafish Bim, Bid exhibited only weak binding to zebrafish Bcl-2 and moderate-to-weak overall lethality in zebrafish embryos and isolated mitochondria. Given that zebrafish Bcl-2 binds strongly to mammalian BID and BIM peptides and proteins, the protein identified as the zebrafish Bid ortholog has different properties than mammalian BID. Overall, our results demonstrate the high degree of functional conservation between zebrafish and mammalian Bcl-2 family proteins, thus validating the zebrafish as a model system to further dissect the molecular mechanisms that regulate apoptosis in future forward genetic and chemical modifier screens.     

Profile of a mammalian sperm receptor

Complementary molecules on the surface of eggs and sperm are responsible for species-specific interactions between gametes during fertilization in both plants and animals. In this essay, several aspects of current research on the mouse egg receptor for sperm, a zona pellucida glycoprotein called ZP3, are addressed. These include the structure, synthesis, and functions of the sperm receptor during oogenesis and fertilization in mice. Several conclusions are drawn from available information. These include (I) ZP3 is a member of a unique class of glycoproteins found exclusively in the extracellular coat (zona pellucida) of mammalian eggs. (II) ZP3 gene expression is an example of oocyte-specific and, therefore, sex-specific gene expression during mammalian development. (III) ZP3 is a structural glycoprotein involved in assembly of the egg extracellular coat during mammalian oogenesis. (IV) ZP3 is a sperm receptor involved in carbohydrate-mediated gamete recognition and adhesion during mammalian fertilization. (V) ZP3 is an inducer of sperm exocytosis (acrosome reaction) during mammalian fertilization. (VI) ZP3 participates in the secondary block to polyspermy following fertilization in mammals. (VII) The extracellular coat of other mammalian eggs contains a glycoprotein that is functionally analogous to mouse ZP3. The unique nature, highly restricted expression, and multiple roles of ZP3 during mammalian development make this glycoprotein a particularly attractive subject for investigation at both the cellular and molecular levels.     

Incorporation of mammalian metabolism into mutagenicity testing

In the 1950's and 1960's it became obvious that many chemicals in daily use were mutagenic or carcinogenic, but there seemed to be little relation between the two activities. As scientists were debating the cause of this discrepancy, it was hypothesized that mammalian metabolism could form highly reactive intermediates from rather innocuous chemicals and that these intermediates could react with DNA and were mutagenic. This commentary presents the historical development of metabolic activation in mutagenicity tests, beginning with Udenfriend's hydroxylation system, which mimics aspects of mammalian metabolism in a purely chemical mixture, and extending through procedures that moved closer and closer to incorporating actual mammalian metabolism into the test systems. The stages include microsomal activation systems, host-mediated assays, incorporation of human P450 genes into the target cells or organisms, and detecting mutations in single cells in vivo. A recent development in this progression is the insertion of recoverable vectors containing mutational targets into the mammalian genome. Since the target genes of transgenic assays are in the genome, they are not only exposed to active metabolites, but they also undergo the same repair processes as endogenous genes of the mammalian genome.     

The Control of Color in Mammals

SYNOPSIS. Recent advances in the biology of mammalian pigmentationare reviewed.Particular attention is given to emerging informationon the integration of pigmentary events occurring at differentlevels of biological organization within mammalian skin andhair. The structural and functional significance of keratinocytesand melanocytes as components of mammalian epidermal melaninunits is viewed from this perspective. New evidence on the natureof genetic, developmental, endocrine, and radiation influenceson performance of melanocytes and the establishment of pigmentarypatterns is summarized.     

Chemical nature of in vivo DNA base damage in hydrogen peroxide-treated mammalian cells.

Hydrogen peroxide is generated in mammalian cells by normal metabolism or by treatment with external agents. Treatment of mammalian cells with this oxidizing agent results in DNA damage. Little is known about the chemical nature of hydrogen peroxide-mediated DNA damage in mammalian cells. Here we report on the chemical characterization of in vivo base damage to nuclear DNA in mammalian cells caused by exposure to H2O2. Chromatin was isolated from cells and analyzed by gas chromatography/mass spectrometry with selected-ion monitoring. Ten DNA base products were identified and quantitated. Modified bases identified were typical hydroxyl radical-induced products of DNA bases. Results indicate involvement of hydroxyl radicals in the mechanism of nuclear DNA damage in mammalian cells caused by H2O2.     

Reticuloendotheliosis virus: detection of immunological relationship to mammalian type C retroviruses.

Reticuloendotheliosis virus (REV) p30 shares cross-reactive determinants and a common NH2-terminal tripeptide with mammalian type C viral p30's. An interspecies competition radioimmunoassay was developed, using iodinated REV p30 and a broadly reactive antiserum to mammalian virus p30's. The avian leukosis-sarcoma viruses and mammalian non-type C retroviruses did not compete in this assay. Previous data indicating that the REV group is not represented completely in normal avian cell DNA lead us to speculate that this may be the first example of interclass transmission, albeit in the remote past, among the Retroviridae.     

哺乳动物卵泡卵母细胞发生的分子调控

哺乳动物卵泡卵母细胞发生的研究一直是发育生物学研究的重点之一。简要叙述了哺乳动物卵泡卵母细胞发生的一般过程,重点分析了原始生殖细胞向卵母细胞分化过程中gdf9、c-kti、BMP4及TGF家族关键基因的表达调控对卵母细胞发生的影响,以及卵母细胞与颗粒细胞间的相互调节作用,介绍了卵母细胞体外发生的最新研究进展及面临的难题等,为进一步研究原始生殖细胞向卵母细胞分化以及卵泡生长发育的机制提供了理论基础。     

Protein and Genome Evolution in Mammalian Cells for Biotechnology Applications

Mutation and selection are the essential steps of evolution. Researchers have long used in vitro mutagenesis, expression, and selection techniques in laboratory bacteria and yeast cultures to evolve proteins with new properties, termed directed evolution. Unfortunately, the nature of mammalian cells makes applying these mutagenesis and whole-organism evolution techniques to mammalian protein expression systems laborious and time consuming. Mammalian evolution systems would be useful to test unique mammalian cell proteins and protein characteristics, such as complex glycosylation. Protein evolution in mammalian cells would allow for generation of novel diagnostic tools and designer polypeptides that can only be tested in a mammalian expression system. Recent advances have shown that mammalian cells of the immune system can be utilized to evolve transgenes during their natural mutagenesis processes, thus creating proteins with unique properties, such as fluorescence. On a more global level, researchers have shown that mutation systems that affect the entire genome of a mammalian cell can give rise to cells with unique phenotypes suitable for commercial processes. This review examines the advances in mammalian cell and protein evolution and the application of this work toward advances in commercial mammalian cell biotechnology.     

Constitutive Activity in an Ancestral Form of Abl Tyrosine Kinase

The c-abl proto-oncogene encodes a nonreceptor tyrosine kinase that is found in all metazoans, and is ubiquitously expressed in mammalian tissues. The Abl tyrosine kinase plays important roles in the regulation of mammalian cell physiology. Abl-like kinases have been identified in the genomes of unicellular choanoflagellates, the closest relatives to the Metazoa, and in related unicellular organisms. Here, we have carried out the first characterization of a premetazoan Abl kinase, MbAbl2, from the choanoflagellate Monosiga brevicollis. The enzyme possesses SH3, SH2, and kinase domains in a similar arrangement to its mammalian counterparts, and is an active tyrosine kinase. MbAbl2 lacks the N-terminal myristoylation and cap sequences that are critical regulators of mammalian Abl kinase activity, and we show that MbAbl2 is constitutively active. When expressed in mammalian cells, MbAbl2 strongly phosphorylates cellular proteins on tyrosine, and transforms cells much more potently than mammalian Abl kinase. Thus, MbAbl2 appears to lack the autoinhibitory mechanism that tightly constrains the activity of mammalian Abl kinases, suggesting that this regulatory apparatus arose more recently in metazoan evolution.