Pluripotent mesenchymal stem cells reside within avian connective tissue matrices

Summary Recent studies have noted the presence of putative stem cells derived from the connective tissues associated with skeletal muscle, heart, and dermis. Long-term continuous cultures of these cells from each tissue demonstrated five distinct phenotypes of mesodermal origin, i.e. muscle, fat, cartilage, bone, and connective tissue. Clonal analysis was performed to determine whether these morphologies were the result of a mixed population of lineage-committed stem cells or the differentiation of pluripotent stem cells or both. Putative stem cells from four tissues (skeletal muscle, dermis, atria, and ventricle) were isolated and cloned. Combined, 1158 clones were generated from the initial cloning and two subsequent subclonings. Plating efficiency approximated 5.8%. Approximately 70% of the 1158 clones displayed a pure stellate morphology, while the remaining clones contained a mixture of stellate, chondrogenic- or osteogenic-like morphologies or both. When cultured in the presence of dexamethasone, cells from all clones differentiated in a time- and concentration-dependent manner into muscle, fat, cartilage, and bone. These results suggest that pluripotent mesenchymal stem cells are present within the connective tissues of skeletal muscle, dermis, and heart and may prove useful for studies concerning the regulation of stem cell differentiation, wound healing, and tissue restoration, replacement and repair.     

Generation of normal progeny by intracytoplasmic sperm injection following grafting of testicular tissue from cloned mice that died postnatally

Animal cloning by nuclear transfer has been successful in several species and was expected to become an alternative reproductive technique. Among the problems associated with this cloning technique, however, are its low success rate and high mortality of cloned animals even if they develop to term. Nuclear transfer has thus come to be considered too difficult to apply as a reproductive technique. The transplantation of male germ cells or pieces of testicular tissue has enabled the induction of spermatogenesis from fetal or postnatal male mice. In the present study, we examined whether functional male gametes could be obtained by the transplantation of pieces of testicular tissue from cloned mice that died immediately after birth with typical aberrant phenotypes, such as large offspring syndrome. Donor testicular tissues were retrieved from cloned mice that died postnatally and were transplanted into the testes of recipient nude mice. Two to three months after transplantation, the grafted donor testicular tissue had grown in the host testis, and histological analysis showed that spermatogenesis occurred within the graft. Intracytoplasmic sperm injection demonstrated that the testicular sperm generated in the grafted donor tissue were able to support full-term development of progeny. These results clearly showed that functional spermatogenesis could be induced by transplanting testicular tissue from cloned mice that died postnatally into recipient mice. The strategy presented here will be applicable to cloned animals of other species, because the xenografting of testicular tissue into mice has been demonstrated previously to be possible.     

Transgenic-cloned pigs systemically expressing red fluorescent protein, Kusabira-Orange

Genetically engineered pigs with cell markers such as fluorescent proteins are highly useful in lines of research that include the tracking of transplanted cells or tissues. In this study, we produced transgenic-cloned pigs carrying a gene for the newly developed red fluorescent protein, humanized Kusabira-Orange (huKO), which was cloned from the coral stone Fungia concinna. The nuclear transfer embryos, reconstructed with fetal fibroblast cells that had been transduced with huKO cDNA using retroviral vector DDeltaNsap, developed efficiently in vitro into blastocysts (28.0%, 37/132). Nearly all (94.6%, 35/37) of the cloned blastocysts derived from the transduced cells exhibited clear huKO gene expression. A total of 429 nuclear transfer embryos were transferred to four recipients, all of which became pregnant and gave birth to 18 transgenic-cloned offspring in total. All of the pigs highly expressed huKO fluorescence in all of the 23 organs and tissues analyzed, including the brain, eyes, intestinal and reproductive organs, skeletal muscle, bone, skin, and hoof. Furthermore, such expression was also confirmed by histological analyses of various tissues such as pancreatic islets, renal corpuscles, neuronal and glial cells, the retina, chondrocytes, and hematopoietic cells. These data demonstrate that transgenic-cloned pigs exhibiting systemic red fluorescence expression can be efficiently produced by nuclear transfer of somatic cells retrovirally transduced with huKO gene.     

Molecular cloning of cDNA encoding the Ca2+ release channel (ryanodine receptor) of rabbit cardiac muscle sarcoplasmic reticulum

We have cloned and sequenced cDNA encoding the Ca2+ release channel (ryanodine receptor) of rabbit cardiac muscle sarcoplasmic reticulum. The cDNA, 16,532 base pairs in length, encodes a protein of 4,969 amino acids with a Mr of 564,711. The deduced amino acid sequence is 66% identical with that of the skeletal muscle ryanodine receptor, but analysis of predicted secondary structures and hydropathy plots suggests that the two isoforms exhibit the same topology in both transmembrane and cytoplasmic domains. A potential ATP binding domain was identified at residues 2619-2652, a potential phosphorylation site at residue 2809, and potential calmodulin binding sites at residues 2775-2807, 2877-2898, and 2998-3016. We suggest that a modulator binding domain in the protein lies between residues 2619 and 3016. Northern blot analysis of mRNA from a variety of tissues demonstrated that the cardiac isoform is expressed in heart and brain, while the skeletal muscle isoform is expressed in both fast- and slow-twitch muscle. No ryanodine receptor mRNA was detected in extracts from smooth muscle or any other non-muscle tissue examined. The two receptors are clearly the products of separate genes, and the gene encoding the cardiac muscle ryanodine receptor was localized to chromosome 1.     

Embryonic origin of skeletal muscle cells in the iris of the duck and quail

Summary The origin of skeletal muscle cells in avian iris muscle was investigated by quantitative analysis of heterochromatin profiles at the electron-microscopic level in irides of six types of quail-duck chimeras. Each of the following tissues was transplanted into the head region from quail to duck between stages 9 and 10: cranial neural crest; trunk neural crest; midbrain and adjacent mesoderm; forebrain; forebrain without neural crest; and forebrain without neural crest and mesoderm. The average ratio of heterochromatin profile to nucleus profile in iris skeletal muscle cells was high (quail type) in the dorsal iris, but low (duck type) in the ventral iris of the chimeras resulting from isotopic transplantation of cranial neural crest. Heterotopic transplantation of trunk neural crest to cranial position resulted in failure of development of skeletal muscle cells in the dorsal iris, but not in the appearance of skeletal muscle cells in the ventral iris. The average ratio of heterochromatin profile to nucleus profile in iris skeletal muscle cells was high in the chimeras resulting from transplantation of midbrain region and the chimeras resulting from transplantation of forebrain region, intermediate in the chimeras resulting from transplantation of forebrain region without neural crest, and low in the chimeras resulting from transplantation of forebrain region without neural crest and mesoderm. These results indicate that the skeletal muscle cells in the dorsal iris are of cranial neural crest origin while those in the ventral iris are not, and could possibly arise from cranial mesoderm.     

Toad Heart Utilizes Exclusively Slow Skeletal Muscle Troponin T: AN EVOLUTIONARY ADAPTATION WITH POTENTIAL FUNCTIONAL BENEFITS

The three isoforms of vertebrate troponin T (TnT) are normally expressed in a muscle type-specific manner. Here we report an exception that the cardiac muscle of toad (Bufo) expresses exclusively slow skeletal muscle TnT (ssTnT) together with cardiac forms of troponin I and myosin as determined using immunoblotting, cDNA cloning, and/or LC-MS/MS. Using RT-PCR and 3'- and 5'-rapid amplification of cDNA ends on toad cardiac mRNA, we cloned full-length cDNAs encoding two alternatively spliced variants of ssTnT. Expression of the cloned cDNAs in Escherichia coli confirmed that the toad cardiac muscle expresses solely ssTnT, predominantly the low molecular weight variant with the exon 5-encoded NH(2)-terminal segment spliced out. Functional studies were performed in ex vivo working toad hearts and compared with the frog (Rana) hearts. The results showed that toad hearts had higher contractile and relaxation velocities and were able to work against a significantly higher afterload than that of frog hearts. Therefore, the unique evolutionary adaptation of utilizing exclusively ssTnT in toad cardiac muscle corresponded to a fitness value from improving systolic function of the heart. The data demonstrated a physiological importance of the functional diversity of TnT isoforms. The structure-function relationship of TnT may be explored for the development of new treatment of heart failure.     

Long-term bovine hematopoietic engraftment with clone-derived stem cells

Therapeutic cloning by somatic cell nuclear transfer offers potential for treatment of a wide range of degenerative disease. Nuclear transplantation with neo (r)-marked somatic nuclei from 10-13-year-old cows was used to generate cloned bovine fetuses. Clone fetal liver (FL) hematopoietic stem cells (HSC) were transplanted into two busulfan-treated and one untreated nuclear donor cows. Hematopoiesis was monitored over 13-16 months by in vitro progenitor and HSC assays. Chimerism was demonstrated by PCR in blood, marrow, lymph nodes, and endothelium, peaking at levels of 9-17% in blood granulocytes but at lower levels in lymphocyte subsets (0.1-0.01%). Circulating progenitors showed high levels of chimerism (up to 60% neo (r+)) with persisting fetal features. At sacrifice, the animal that had no pre-transplant myelosupression showed persisting donor cells in blood and lymph nodes, and in marrow 0.25% of progenitor cells and a detectable fraction of stem cells were neo (r+). The fetal HSC showed a 10-fold competition advantage over adult HSC. Cloning generated histocompatible HSC capable of long-term multilineage engraftment in a large animal model.     

Skeletal myogenic progenitors originating from embryonic dorsal aorta coexpress endothelial and myogenic markers and contribute to postnatal muscle growth and regeneration

Skeletal muscle in vertebrates is derived from somites, epithelial structures of the paraxial mesoderm, yet many unrelated reports describe the occasional appearance of myogenic cells from tissues of nonsomite origin, suggesting either transdifferentiation or the persistence of a multipotent progenitor. Here, we show that clonable skeletal myogenic cells are present in the embryonic dorsal aorta of mouse embryos. This finding is based on a detailed clonal analysis of different tissue anlagen at various developmental stages. In vitro, these myogenic cells show the same morphology as satellite cells derived from adult skeletal muscle, and express a number of myogenic and endothelial markers. Surprisingly, the latter are also expressed by adult satellite cells. Furthermore, it is possible to clone myogenic cells from limbs of mutant c-Met-/- embryos, which lack appendicular muscles, but have a normal vascular system. Upon transplantation, aorta-derived myogenic cells participate in postnatal muscle growth and regeneration, and fuse with resident satellite cells.The potential of the vascular system to generate skeletal muscle cells may explain observations of nonsomite skeletal myogenesis and raises the possibility that a subset of satellite cells may derive from the vascular system.     

Molecular Cloning of a Gene on Chromosome 19q12 Coding for a Novel Intracellular Protein: Analysis of Expression in Human and Mouse Tissues and in Human Tumor Cells, Particularly Reed–Sternberg Cells in Hodgkin Disease

A novel protein, named NNX3, was molecularly characterized by cloning its cDNA, and its gene was mapped to chromosome 19q12. The equivalent mouse cDNA and gene were also cloned to allow us to analyze expression in murine in addition to human cells and tissues. Human and mouse NNX3 genes are composed of nine exons coding for proteins that are unrelated to any known protein. Signal peptides and hydrophobic domains are absent, corroborating their localization in the cytoplasm in transfected Cos cells. In Western blotting and immunoprecipitation, human NNX3 appeared as a doublet ofM_r64K–66K, while mouse NNX3 was a 70-kDa protein, both apparently much larger than the predicted 50 kDa, due in part to a stretch of 16–18 acidic residues hinging two nearly equally sized domains. In addition, phosphorylation of serine residues was demonstrated. Putative nuclear targeting signals were predicted, but NNX3 protein and two truncated versions remained localized in the cytoplasm of transfected Cos cells. NNX3 was expressed in embryonic and adult mouse tissues, particularly in brain, muscle, and lung. The expression of human NNX3 was most notable in human skeletal muscle and in ganglion cells and was also evident in human tumors and derived cell lines. This was confirmed by entries appearing in the GenBank EST database during the later phase of this study, representing partial NNX3 cDNA isolated from diverse neoplastic and developing tissues. Surprisingly, NNX3 was immunochemically detected in Reed–Sternberg cells of Hodgkin disease, in parallel with restin, a cytoplasmic protein we previously characterized (J. Delabieet al.,1993,Leuk. Lymphoma 12,21–26). The cloning and comprehensive molecular analysis of NNX3 as presented will form the basis for elucidating its function and, conversely, will constitute a marker for Reed–Sternberg cells in Hodgkin disease.     

Direct gene transfer and expression into rat heart in vivo

We found previously that genes injected into skeletal muscle can be taken up by myofibers and expressed. In the present study we found that myocardial cells can also express a variety of reporter genes injected into myocardium as efficiently as skeletal myofibers, while the cells of several other tissues cannot. The inability of tissues other than striated muscle to express injected DNA is not due to technical difficulties of injection because injected DNA was detected in these other tissues by PCR analysis. These results suggest that skeletal and cardiac muscle cells have unique features such as T tubules that may play a critical role in DNA uptake. Expression in cardiac muscle was stable for only two weeks, possibly because of an immune response against the transfected cells. The ability to directly transfer genes into myocardial cells raises the possibility of gene therapy for both acquired and genetic heart diseases.     

Simultaneous expression of skeletal muscle and heart actin proteins in various striated muscle tissues and cells. A quantitative determination of the two actin isoforms

A procedure was developed to determine the percentage of skeletal muscle actin and cardiac actin present in different striated muscle tissues. The method was applied to 2 mg of actin mixtures isolated from various origins. All samples show simultaneous expression of both striated muscle isoactins, with the cardiac actin being the major form (congruent to 80%) in 11-day-old chick embryonic leg muscle, decreasing to approximately 50% values in the late fetal stage of chicken, mouse, and in fused mouse muscle cell cultures and becoming the minor species (less than 5%) in adult skeletal muscle tissues. We also find a significant amount (up to 20%) of the skeletal muscle isoform in adult heart (ventricle) of porcine, bovine, and human origin and no differences in muscle actin ratios in human atrium and ventriculum cells. Similarly, no significant variation in the actin ratios was observed between a normal heart and a heart from a patient with hereditary obstructive myopathy. For those cells and tissues where comparison with levels of mRNA was possible we mostly find a good correlation between the relative ratios of expression of cardiac and skeletal actin proteins and mRNAs.     

Molecular cloning and characterization of a novel calcium channel from rabbit brain.

The complete amino acid sequence of a novel calcium channel (designated BII) from rabbit brain has been deduced by cloning and sequencing the cDNA. The BII calcium channel is structurally more closely related to the BI calcium channel than to the cardiac and skeletal muscle L-type calcium channels. Blot hybridization analysis of RNA from different tissues and from different regions of the brain shows that the BII calcium channel is distributed predominantly in the brain, being abundant in the cerebral cortex, hippocampus and corpus striatum.     

Proenkephalin expression and enkephalin release are widely observed in non-neuronal tissues

Enkephalins are opioid peptides that are found at high levels in the brain and endocrine tissues. Studies have shown that enkephalins play an important role in behavior, pain, cardiac function, cellular growth, immunity, and ischemic tolerance. Our global hypothesis is that enkephalins are released from non-neuronal tissues in response to brief ischemia or exercise, and that this release contributes to cardioprotection. To identify tissues that could serve as potential sources of enkephalins, we used real-time PCR, Western blot analysis, ELISA, immunofluorescence microscopy, and ex vivo models of enkephalin release. We found widespread expression of preproenkephalin (pPENK) mRNA and production of the enkephalin precursor protein proenkephalin (PENK) in rat and mouse tissues, as well as in tissues and cells from humans and pigs. Immunofluorescence microscopy with anti-enkephalin antisera demonstrated immunoreactivity in rat tissues, including heart and skeletal muscle myocytes, intestinal and kidney epithelium, and intestinal smooth muscle cells. Finally, isolated tissue studies showed that heart, skeletal muscle, and intestine released enkephalins ex vivo. Together our studies indicate that multiple non-neuronal tissues produce PENK and release enkephalins. These data support the hypothesis that non-neuronal tissues could play a role in both local and systemic enkephalin-mediated effects.     

Remarkable differences in telomere lengths among cloned cattle derived from different cell types

Regarding cloned animals, interesting questions have been raised as to whether cloning restores cellular senescence undergone by their donor cells and how long cloned animals will be able to live. Focusing our attention on differences in telomere lengths depending on the tissue, we had produced 14 cloned cattle by using nuclei of donor cells derived from muscle, oviduct, mammary, and ear skin. Here, we show remarkable variation in telomere lengths among them using Southern blot analysis with telomere-specific probe. Telomere lengths in cloned cattle derived from muscle cells of an old bull were longer than those of a donor animal but were within the variation in normal calves. On the other hand, those derived from oviductal and mammary epithelial cells of an equally old cow were surprisingly shorter than any found in control cattle. The telomere lengths of cloned cattle derived from fibroblasts and oviductal epithelial cells of younger cattle showed the former and the latter results, respectively. In both cases, however, less telomere erosion or telomere extension from nuclear transfer to birth in most cloned cattle was observed in comparison with telomere erosion from fertilization to birth in control cattle. Embryonic cell-cloned cattle and their offspring calves were also shown to have telomeres longer than those in age-matched controls. These observations indicate that cloning does not necessarily restore the telomere clock but, rather, that nuclear transfer itself may commonly trigger an elongation of telomeres, probably more or less according to donor cell type. Remarkable variations among cloned cattle are suggested to be caused by variation in telomere length among donor cells and more or less elongation of telomere lengths induced by cloning.