Skeletal muscle injury can lead to severe motor deficits that adversely affect movement and quality of life. Current surgical treatments for skeletal muscle are hindered by the poor formation of organized myotube bundles at the wound site. Tissue-engineered skeletal muscle constructs to date have been unable to generate high degrees of myotube density and alignment. Generating a suitable in vitro tissue-engineered skeletal muscle construct requires the design of a scaffold that recapitulates the structural combination of nanoscale collagen fibrils and aligned microscale basal lamina tracks present in the native extracellular matrix (ECM). We hypothesized that a 3D aligned tubular porous scaffold containing aligned nanofibers inside the pores can mimic the native muscle tissue environment. We constructed a laminar section of the hypothesized scaffold with aligned chitosan-PCL nanofibers arranged co-axially with the aligned microscale chitosan scaffold bands to mimic the required myogenic environment. A 6-day study of C2C12 mouse myoblast cells cultured on this hybrid scaffold indicated that the nanofibers and scaffold bands in the scaffold played a synergetic role in directing cell orientation, interaction, migration and organization. Our results showed that aligned nanofibers mediated cell alignment and the aligned scaffold bands induced the formation of a more compact assembly of myotube cells as compared to various control substrates including chitosan films, nanofibers, and chitosan bands. The expression levels of both early and late-stage myogenic differentiation genes associated with myogenin and myosin heavy chain, respectively, were higher on the hybrid substrate than on control substrates. Our study suggests that the combination of nano and microscale topological features in the ECM can direct myogenic differentiation, and the hybrid material has the potential to improve the outcome of skeletal tissue engineering.
Changes in mitochondrial DNA (mtDNA) content in cancers have been reported with controversial results, probably due to small sample size and variable pathological conditions. In this study, mtDNA content in 302 breast tumor/surrounding normal tissue pairs were evaluated and correlated with the clinico-pathological characteristics of tumors. Overall, mtDNA content in tumor tissues is significantly lower than that in the surrounding normal tissues, P < 0.00001. MtDNA content in tumor tissues decreased with increasing tumor size. However, when the tumor is very large (>50 cm3), mtDNA content started to increase. Similarly, mtDNA content decreased from grades 0 and I to grade II tumors, but increased from grade II to grade III tumors. Tumors with somatic mtDNA alterations in coding region have significantly higher mtDNA content than tumors without somatic mtDNA alterations (P < 0.001). Tumors with somatic mtDNA alterations in the D-Loop region have significantly lower mtDNA content (P < 0.001). Patients with both low and high mtDNA content in tumor tissue have significantly higher hazard of death than patients with median levels of mtDNA content. mtDNA content in tumor tissues change with tumor size, grade, and ER/PR status; significant deviation from the median level of mtDNA content is associated with poor survival.
Bad, an inducer of programmed cell death, was recently isolated from a mouse cDNA library by its ability to bind to the anti-apoptotic protein BCL-2. Sequence analysis suggested that Bad was a member of the BCL-2 gene family that encodes both inducers and inhibitors of programmed cell death. To further analyze the role of BAD in the network of homo-and heterodimers formed by the BCL-2 family, we have cloned the human homologue of BAD and assessed its biological activity and its interactions with wild type and mutant BCL-2 family proteins. Our results indicate that the human BAD protein, like its mouse homologue, is able to induce apoptosis when transfected into mammalian cells. Furthermore, in yeast two-hybrid assays as well as quantitative in vitro interaction assays, human Bad interacted with BCL-2 and BCL-X L . Sequence alignments of human BAD revealed the presence of a BH-3 homology domain as seen in other BCL-2 family proteins. Peptides derived from this domain were able to completely inhibit the dimerization of BAD with BCL-X L . Thus, as previously shown for BAX, BAK, BCL-2, and BCL-X L , the BH3 domain of BAD is required for its dimerization with other BCL-2 family proteins. BAD was further analyzed for its ability to bind to various mutants of BCL-2 and BCL-X L that have lost the ability to bind BAX and BAK, some of which retain biological activity and some of which do not. Surprisingly, all of the mutated BCL-2 and BCL-X L proteins analyzed strongly interacted with human BAD. Our data thus indicate that mutations in BCL-2 and BCL-X L can differentially affect the heterodimeric binding of different death-promoting proteins and have implications concerning the relationship between heterodimerization and biological activity.The BCL-2 family of proteins consists of inhibitors and inducers of programmed cell death or apoptosis (1-3). Inhibitors include the BCL-2 (4, 5) and BCL-X L proteins (6) and inducers include BAX, BAK, and BCL-X S (6 -10). These proteins have been shown to form a network of homo-and heterodimers (11). A number of studies suggest that dimer formation is essential for the biological activity of these molecules. For example, mutagenesis data have demonstrated a correlation between BCL-2 activity and the ability to form heterodimers with BAX (12). However, other experiments with BCL-X L suggested that dimerization with Bax was not necessary for biological activity (13).Bad was originally cloned from mouse cDNA by its ability to bind to BCL-2, both in yeast two-hybrid interactions and by direct biochemical interaction (14). It was subsequently shown to interact more strongly with BCL-X L than with BCL-2, and in functional studies it antagonized the protective effect of BCL-X L . To date, the human homologue has not been reported. The sequences of the BCL-2 family proteins show several regions of clustered conserved residues, termed by some investigators BH-1 to BH-4 domains (12,15,16). The crystal and NMR structures of BCL-X L show a potential binding pocket on the surface of the molecule f...
Mitochondrial DNA (mtDNA) has been proposed to be involved in carcinogenesis because of its high susceptibility to oxidative DNA damage and limited repair mechanisms. For investigation of the potential role of somatic mtDNA mutations in the tumorigenesis of oral cancer, we screened the occurrence of mtDNA mutations by the temporal temperature gradient gel electrophoresis method. We amplified the entire mitochondrial genome by use of 32 pairs of overlapping primers, and to identify the mutations, we sequenced DNA fragments showing different banding patterns between normal and tumor mtDNA. Fourteen of eighteen (77.8%) oral carcinomas displayed somatic mtDNA mutations, with a total of 26 mutations. Among them, six were in the mRNA coding region. Three were missense mutations (C14F, H186R, T173P) in NADH dehydrogenase subunit 2, and one was a frameshift mutation, 9485delC, in cytochrome c oxidase subunit III. Eight (44%) tumors had insertion or deletion mutations in the nucleotide position 303-309 poly C region of the D-loop. Multiple large deletions were also observed. Our results demonstrate that somatic mtDNA mutations occur in oral cancer. Some missense and frameshift mutations may play an important role in the tumorigenesis of this carcinoma. More extensive biochemical and molecular studies will be necessary for determining the pathologic effect of these somatic mutations.
Cell cycle checkpoints contribute to survival after exposure to ionizing radiation (IR) by arresting the cell cycle and permitting repair. As such, yeast and mammalian cells lacking checkpoints are more sensitive to killing by IR. We reported previously that Drosophila larvae mutant for grp (encoding a homolog of Chk1) survive IR as well as wild type despite being deficient in cell cycle checkpoints. This discrepancy could be due to differences either among species or between unicellular and multicellular systems. Here, we provide evidence that Grapes is needed for survival of Drosophila S2 cells after exposure to similar doses of IR, suggesting that multicellular organisms may utilize checkpoint-independent mechanisms to survive irradiation. The dispensability of checkpoints in multicellular organisms could be due to replacement of damaged cells by regeneration through increased nutritional uptake and compensatory proliferation. In support of this idea, we find that inhibition of nutritional uptake (by starvation or onset of pupariation) or inhibition of growth factor signaling and downstream targets (by mutations in cdk4, chico, or dmyc) reduced the radiation survival of larvae. Further, some of these treatments are more detrimental for grp mutants, suggesting that the need for compensatory proliferation is greater for checkpoint mutants. The difference in survival of grp and wild-type larvae allowed us to screen for small molecules that act as genotype-specific radiation sensitizers in a multicellular context. A pilot screen of a small molecule library from the National Cancer Institute yielded known and approved radio-sensitizing anticancer drugs. Since radiation is a common treatment option for human cancers, we propose that Drosophila may be used as an in vivo screening tool for genotype-specific drugs that enhance the effect of radiation therapy.
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