Efficient differentiation of human iPSC‐derived mesenchymal stem cells to chondroprogenitor cells

Induced pluripotent stem cells (iPSC) hold tremendous potential for personalized cell‐based repair strategies to treat musculoskeletal disorders. To establish human iPSCs as a potential source of viable chondroprogenitors for articular cartilage repair, we assessed the in vitro chondrogenic potential of the pluripotent population versus an iPSC‐derived mesenchymal‐like progenitor population. We found the direct plating of undifferentiated iPSCs into high‐density micromass cultures in the presence of BMP‐2 promoted chondrogenic differentiation, however these conditions resulted in a mixed population of cells resembling the phenotype of articular cartilage, transient cartilage, and fibrocartilage. The progenitor cells derived from human iPSCs exhibited immunophenotypic features of mesenchymal stem cells (MSCs) and developed along multiple mesenchymal lineages, including osteoblasts, adipocytes, and chondrocytes in vitro. The data indicate the derivation of a mesenchymal stem cell population from human iPSCs is necessary to limit culture heterogeneity as well as chondrocyte maturation in the differentiated progeny. Moreover, as compared to pellet culture differentiation, BMP‐2 treatment of iPSC‐derived MSC‐like (iPSC–MSC) micromass cultures resulted in a phenotype more typical of articular chondrocytes, characterized by the enrichment of cartilage‐specific type II collagen (Col2a1), decreased expression of type I collagen (Col1a1) as well as lack of chondrocyte hypertrophy. These studies represent a first step toward identifying the most suitable iPSC progeny for developing cell‐based approaches to repair joint cartilage damage. J. Cell. Biochem. 114: 480–490, 2013. © 2012 Wiley Periodicals, Inc.     

Chloroplast Biogenesis Controlled by DELLA-TOC159 Interaction in Early Plant Development

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Environmental agents affect skeletal growth and development

In this treatise we will examine complexities in the development and function of cells of the musculoskeletal system. Specifically, the role of chondrocytes and their ontogeny and osteoblasts and their ontogeny will be discussed as they regulate cartilage and bone formation. This background information will provide the foundation for evaluating the effects of environmental toxicants on skeletal development. A number of agents such as heavy metals (i.e. lead) and polycyclic aromatic hydrocarbons (i.e. pesticides and cigarette smoke) interact with cells of the skeletal system and adversely affect development. These agents have not been of major research interest, nevertheless, given changes in the environmental profile of the United States and other developed countries, it is important that we understand their effects in bone and cartilage. Research in this area will identify strategies that may be used to help prevent musculoskeletal diseases due to toxicant exposure.     

Towards a new approach of controlling endophytic bacteria associated with date palm explants using essential oils,aqueous and methanolic extracts from medicinal and aromatic plants

Plant Cell, Tissue and Organ Culture (PCTOC) - We identified two strains of endophytic bacteria associated with date palm explants by 16S rRNA gene amplification and sequencing, and we explored...     

Association between Paraoxonase 1 (PON1) Polymorphisms and the Risk of Acute Coronary Syndrome in a North African Population

The purpose of the present study was to investigate the distribution of PON1 Q192R and L55M polymorphisms and activities in a North African population and to determine their association with cardiovascular complications. The prevalence of the QQ, QR, RR, LL, LM, and MM genotypes in the study population was 55.4%, 34.09%, 9.83%, 41.97%, 48.20%, and 9.83% respectively. The Q, R, L, and M alleles had a gene frequency of 0.755, 0.245, 0.67, and 0.33, respectively. The PON1 192 RR genotype was significantly more prevalent among ACS patients than among healthy subjects. There was a 4.33-fold increase in the risk of ACS in subjects presenting the PON1 192 RR genotype compared to those with the QQ genotype (OR=4.33; 95% CI=1.27–17.7). There was a significantly different distribution of PON1 L55M in the ACS patient groups (UA, STEMI, NSTEMI). Moreover, individuals presenting the PON1 55MM genotype present a higher risk for ACS than those with LL genotype (OR=3.69; 95% CI=1.61–11.80). Paraoxonase activities were significantly lower in coronary patients than in healthy subjects. The decrease in PON1 activity was inversely correlated with the number of concomitant risk factors for CVD (r=0.57, p<0.0001). The results of the present study suggested that the PON1 R and M alleles may play a role in the pathogenesis of cardiac ischemia in our North African population and that a decrease in PON1 activity may be a valuable marker for monitoring the development of the atherosclerosis process and the associated cardiovascular complications.     

Insect Virus Proteins (FALPE and p10) Self-Associate To Form Filaments in Infected Cells

Entomopoxviruses and baculoviruses are pathogens of insects which replicate in the cytoplasm and nuclei of their host cells, respectively. During the late stages of infection, both groups of viruses produce occlusion bodies which serve to protect virions from the external environment. Immunofluorescence and electron microscopy studies have shown that large bundles of filaments are associated with these occlusion bodies. Entomopoxviruses produce cytoplasmic fibrils which appear to be composed of the filament-associated late protein of entomopoxviruses (FALPE). Baculoviruses, on the other hand, yield filaments in the nuclei and cytoplasm of the infected cell which are composed of a protein called p10. Despite significant differences in their sequences, FALPE and p10 have similar hydrophilicity profiles, and each has a proline-rich stretch of amino acids at its carboxyl terminus. Evidence that FALPE and p10 could produce filaments in the absence of other viral proteins is presented. When FALPE was expressed in insect cells from a recombinant baculovirus, filaments similar to those produced by the wild-type Amsacta moorei entomopoxvirus were observed. In addition, when expression plasmids containing FALPE or p10 genes were transfected into Vero monkey kidney cells, filament structures similar to those found in infected insect cells were produced. The manner in which FALPE and p10 subunits interact to form polymers was investigated through deletion and site-specific mutagenesis in conjunction with immunofluorescence microscopy, yeast two-hybrid protein interaction analysis, and chemical cross-linking of adjacent molecules. These studies indicated that the amino termini of FALPE and p10 were essential for subunit interaction. Although deletion of the carboxy termini did not affect this interaction, it did inhibit filament formation. In addition, modification of several potential sites for phosphorylation also abolished filament assembly. We concluded that although the sequences of FALPE and p10 were different, the structural and functional properties of the two polypeptides appeared to be similar.Cytoskeletal elements have previously been demonstrated to be involved in several aspects of virus assembly (39, 66). For example, vaccinia virus has been shown to associate with actin during its release from the plasma membrane (15), while adenovirus is transported through the cytoplasm to the nucleus through its interaction with microtubules (17, 38). Actin has been implicated in the transport of baculovirus nucleocapsids to the nucleus (10). Other viruses contain actin in their envelopes along with viral surface glycoproteins, implying some role in the budding process (34, 54, 58). In addition, cytochalasin D, a disruptor of microfilaments, has been shown to impair the assembly of a number of different viruses (18, 42, 45). Most viruses use preexisting microtubule or microfilament proteins derived from host cells in these processes. However, we have recently demonstrated that insect poxviruses establish their own filament network during the later stages of infection, using a protein encoded by the viral genome (2).Entomopoxviruses (EPVs) are insect pathogens which replicate in the cytoplasm of infected cells and are members of the poxvirus family (reviewed in references 3 to 5 and 22). The genomes of these viruses consist of linear double-stranded DNA molecules which are 130 to 300 kb in length. Amsacta moorei EPV (AmEPV) can be grown in cultured insect cells and is the most studied member of this group of viruses (22–25, 27, 40, 50). AmEPV derives its name from the Indian red army worm, a larva from the Lepidoptera family and the host from which the virus was originally isolated (23, 25, 50). Baculoviruses also infect Lepidoptera larvae but instead replicate in the nuclei of their host cells (44). A number of baculoviruses have been studied, but knowledge of Autographa californica nuclear polyhedrosis virus (AcNPV), which infects a wide variety of larvae including that of the alfalfa leaf hopper, is most extensive (44). This virus is used routinely to produce recombinant proteins in insect virus expression systems (36, 44, 46, 49).A common property of EPVs and baculoviruses is the formation of large intracellular structures known as occlusion bodies which assemble during the late stages of viral infection. Virions are embedded within these occlusion bodies, and the process serves to protect the virus from the external environment. In the case of baculoviruses, the occlusion bodies are called polyhedra and are composed predominantly of a 31-kDa protein called polyhedrin (52). The occlusion bodies of EPVs are known as spheroids and consist mainly of a 110-kDa protein known as spheroidin (6, 9, 27, 55). Spheroidin and polyhedrin do not appear to exhibit sequence homology (6, 27, 52). A multilamellar envelope also appears to surround both polyhedra and spheroids and may help to stabilize these structures during assembly (2, 53).During the late phases of AmEPV and baculovirus infections, large bundles of filaments also appear to accumulate in the infected insect cells. In the case of AmEPV, these structures are present in the cytoplasm (2, 22, 23, 40), while those found in cells infected with baculoviruses reside both in the cytoplasm and in the nucleus (1, 14, 57). Baculovirus fibrils are composed primarily of a 10-kDa protein called p10 (47, 59). The p10 gene sequences from AcNPV, Orgyia pseudotsugata nuclear polyhedrosis virus (OpNPV), Bombyx mori nuclear polyhedrosis virus, Perina nuda nuclear polyhedrosis virus, Spodoptera exigua nuclear polyhedrosis virus (SeNPV), and Choristoneura fumiferana nuclear polyhedrosis virus (CfNPV) have been reported (13, 32, 35, 66–68). Although the different p10 protein sequences only exhibit 39 to 51% identity and molecules from different species cannot interact with one another, it is believed that the polypeptides must be structurally and functionally similar (61, 66). Deletion mutagenesis of AcNPV p10 has demonstrated that both the amino- and carboxy-terminal regions of this protein are necessary for the formation of filaments in the infected cell (60). Other studies have assigned an aggregation function to the amino-terminal half of p10 (63, 65), and it has been shown that this region contains a coiled-coil domain which is conserved among the different baculoviruses (66). It is tempting to speculate that p10 aggregation is the result of coiled-coil interaction, but direct evidence for this hypothesis is lacking. The precise role of the carboxy terminus of p10 is still unclear, although it has been proposed to interact with tubulin (11). Deletion of the entire p10 open reading frame (ORF) through homologous recombination produces a mutant virus which is still capable of replication both in vitro and in vivo but produces fragile polyhedra with fragmented polyhedral envelopes (26, 64, 65). The p10 protein has also been implicated in disintegration of the nuclear envelope of the host cell, and this function appears to be associated with the carboxy terminus of this protein (61, 65).Our laboratory (2) recently demonstrated that the cytoplasmic filaments, which characterize the late stages of infection by AmEPV, are composed primarily of a 156-amino-acid protein called FALPE (filament-associated late protein of EPVs). These filaments are closely associated with the spheroids and their membrane envelopes. FALPE is a phosphoprotein which migrates on sodium dodecyl sulfate (SDS)-polyacrylamide gels as a 25/27-kDa doublet. This protein also contains an unusual proline-glutamic acid repeat region spanning 20 residues in the carboxy terminus of the polypeptide. The ultrastructure and close association of this protein with the occlusion bodies of AmEPV suggested that FALPE and p10 played analogous roles during infections by the respective viruses.This article addresses the structural and functional similarities between FALPE and p10. These two viral proteins are known to be major components of filamentous structures, but it is not known whether additional viral or cellular proteins cooperate during the polymerization process. In this report, we provide insight into the mechanisms which produce filaments in cells infected with either baculoviruses or EPVs. We demonstrate that p10 and FALPE can produce filaments in the absence of other viral gene products. Using the yeast two-hybrid system and a chemical cross-linking agent, we obtained evidence for self-association of either FALPE or p10. Finally, the polypeptide regions of FALPE and p10 which are required for self-association and subsequent filament formation are mapped.     

Significance of the 2-O-sulfo group of L-iduronic acid residues in heparin on the growth inhibition of bovine pulmonary artery smooth muscle cells

Heparin inhibits the growth of several cell types in vitro, including bovine pulmonary artery smooth muscle cells (BPASMCs). To understand more about the heparin structure required for endogenous activity, chemically modified derivatives of native heparin and glycol-split heparin, namely, 2-O-desulfonated iduronic/glucuronic acid residues in heparin, and 2-O-desulfonated iduronic residues in glycol-split heparin were prepared. These were assayed for their antiproliferative potency on cultured BPASMCs. All of the 2-O-desulfonated heparin derivatives had significantly decreased less antiproliferative activity on BPASMCs. These results suggest that the 2-O-sulfo group of iduronic acid residues in heparin's major sequence is essential for the antiproliferative properties of heparin. The size of heparin does not affect the growth-inhibitory properties of heparin on BPASMCs at the three dose levels examined.     

Direct peptide interaction with surface glycosaminoglycans contributes to the cell penetration of maurocalcine

Maurocalcine (MCa), initially identified from a Tunisian scorpion venom, defines a new member of the family of cell penetrating peptides by its ability to efficiently cross the plasma membrane. The initiating mechanistic step required for the cell translocation of a cell penetrating peptide implicates its binding onto cell surface components such as membrane lipids and/or heparan sulfate proteoglycans. Here we characterized the interaction of wild-type MCa and MCa K20A, a mutant analogue with reduced cell-penetration efficiency, with heparin (HP) and heparan sulfates (HS) through surface plasma resonance. HP and HS bind both to MCa, indicating that heparan sulfate proteoglycans may represent an important entry route of the peptide. This is confirmed by the fact that (i) both compounds bind with reduced affinity to MCa K20A and (ii) the cell penetration of wild-type or mutant MCa coupled to fluorescent streptavidin is reduced by about 50% in mutant Chinese hamster ovary cell lines lacking either all glycosaminoglycans (GAGs) or just HS. Incubating MCa with soluble HS, HP, or chondroitin sulfates also inhibits the cell penetration of MCa-streptavidin complexes. Analyses of the cell distributions of MCa/streptavidin in several Chinese hamster ovary cell lines show that the distribution of the complex coincides with the endosomal marker Lyso-Tracker red and is not affected by the absence of GAGs. The distribution of MCa/streptavidin is not coincident with that of transferrin receptors nor affected by a dominant-negative dynamin 2 K44A mutant, an inhibitor of clathrin-mediated endocytosis. However, entry of the complex is greatly diminished by amiloride, indicating the importance of macropinocytosis in MCa/streptavidin entry. It is concluded that (i) interaction of MCa with GAGs quantitatively improves the cell penetration of MCa, and (ii) GAG-dependent and -independent MCa penetration rely similarly on the macropinocytosis pathway.     

BMP-2/4 and BMP-6/7 differentially utilize cell surface receptors to induce osteoblastic differentiation of human bone marrow-derived mesenchymal stem cells

Bone morphogenetic proteins (BMPs) are members of the transforming growth factor-beta superfamily of growth factors and are used clinically to induce new bone formation. The purpose of this study was to evaluate receptor utilization by BMP-2, BMP-4, BMP-6, and BMP-7 in primary human mesenchymal stem cells (hMSC), a physiologically relevant cell type that probably mediates the in vivo effects of BMPs. RNA interference-mediated gene knockdown revealed that osteoinductive BMP activities in hMSC are elicited through the type I receptors ACVR1A and BMPR1A and the type II receptors ACVR2A and BMPR2. BMPR1B and ACVR2B were expressed at low levels and were not found to play a significant role in signaling by any of the BMPs evaluated in this study. Type II receptor utilization differed significantly between BMP-2/4 and BMP-6/7. A greater reliance on BMPR2 was observed for BMP-2/4 relative to BMP-6/7, whereas ACVR2A was more critical to signaling by BMP-6/7 than BMP-2/4. Significant differences were also observed for the type I receptors. Although BMP-2/4 used predominantly BMPR1A for signaling, ACVR1A was the preferred type I receptor for BMP-6/7. Signaling by both BMP-2/4 and BMP-6/7 was mediated by homodimers of ACVR1A or BMPR1A. A portion of BMP-2/4 signaling also required concurrent BMPR1A and ACVR1A expression, suggesting that BMP-2/4 signal in part through ACVR1A/BMPR1A heterodimers. The capacity of ACVR1A and BMPR1A to form homodimers and heterodimers was confirmed by bioluminescence resonance energy transfer analyses. These results suggest different mechanisms for BMP-2/4- and BMP-6/7-induced osteoblastic differentiation in primary hMSC.     

Novel compound heterozygous mutations in the <Emphasis Type="Italic">GPR98</Emphasis> (<Emphasis Type="Italic">USH2C</Emphasis>) gene identified by whole exome sequencing in a Moroccan deaf family

In the present work, we identified two novel compound heterozygote mutations in the GPR98 (G protein-coupled receptor 98) gene causing Usher syndrome. Whole-exome sequencing was performed to study the genetic causes of Usher syndrome in a Moroccan family with three affected siblings. We identify two novel compound heterozygote mutations (c.1054C?>?A, c.16544delT) in the GPR98 gene in the three affected siblings carrying post-linguale bilateral moderate hearing loss with normal vestibular functions and before installing visual disturbances. This is the first time that mutations in the GPR98 gene are described in the Moroccan deaf patients.