Alba de Martino

Tissue damage and senescence provide critical signals for cellular reprogramming in vivo

For cell reprogramming, context matters Differentiated cells in a culture dish can assume a new identity when manipulated to express four transcription factors. This “reprogramming” process has sparked interest because conceivably it could be harnessed as a therapeutic strategy for tissue regeneration. Mosteiro et al. used a mouse model to study the signals that promote cell reprogramming in vivo. They found that the factors that trigger reprogramming in vitro do the same in vivo; however, they also inflict cell damage. The damaged cells enter a state of senescence and begin secreting certain factors that promote reprogramming, including an inflammatory cytokine called interleukin-6. Thus, in the physiological setting, cell senescence may create a tissue context that favors reprogramming of neighboring cells. Science, this issue p. 10.1126/science.aaf4445 In mice, senescent cells created by tissue damage induce reprogramming of neighboring cells, enhancing tissue repair. INTRODUCTION The ectopic expression of transcription factors OCT4, SOX2, KLF4, and cMYC (OSKM) enables reprogramming of adult differentiated cells into pluripotent cells, known as induced pluripotent stem cells (iPSCs), that are functionally equivalent to embryonic stem cells. Expression of OSKM in vivo leads to widespread cell dedifferentiation and reprogramming within tissues and eventually to the formation of teratomas (tumors arising from iPSCs). The molecular mechanisms operating during in vitro OSKM-driven reprogramming have been extensively characterized; however, little is known about in vivo reprogramming. RATIONALE The process of OSKM reprogramming is inefficient both in vitro and in vivo. A number of cell-intrinsic barriers have been identified in vitro, most of which are activated by cellular damage and are particularly prominent in aged cells. Mechanistically, these cell-intrinsic barriers for reprogramming are primarily mediated by the tumor suppressors p53, p16INK4a, and ARF (the latter two are encoded by the Ink4a/Arf gene locus). In this work, we have investigated the effect of these tumor suppressors, cellular damage, and aging on in vivo reprogramming. RESULTS We found that the expression of OSKM in vivo not only triggers reprogramming of some cells but also inflicts extensive damage on many other cells, driving them into a state known as cellular senescence. Senescent cells are characterized by their inability to proliferate and by their secretion of inflammatory cytokines. We have observed a positive correlation between senescence and OSKM-driven reprogramming. For example, tissues lacking p16INK4a/ARF do not undergo senescence, and their ability to reprogram is severely compromised. By contrast, in tissues lacking p53, damage is rampant; this leads to maximal levels of senescence, exacerbated cytokine production, and increased in vivo reprogramming. To explore the connection between senescence and reprogramming, we manipulated these processes in vivo through pharmacological interventions. In particular, an increase in senescence produced by palbociclib (a drug that functionally mimics p16INK4a) results in higher levels of reprogramming. Conversely, a reduction in senescence achieved by navitoclax (a proapoptotic drug with selectivity against senescent cells) leads to decreased in vivo reprogramming. We found that the cross-talk between senescence and reprogramming is mediated by the cytokine-rich microenvironment associated with senescent cells. This is based, among other evidence, on the observation that pharmacological inhibition of NFκB, a major driver of cytokine production, reduces in vivo reprogramming. Analysis of the inflammatory cytokines produced by senescent cells, both in vivo and in vitro, led us to identify interleukin-6 (IL-6) as a critical secreted factor responsible for the ability of senescent cells to promote reprogramming. In support of this, blockade of IL-6 or its downstream kinase effector PIM potently reduced in vivo reprogramming. These observations can be recapitulated in vitro, where reprogramming efficiency is strongly enhanced by the presence of damaged cells or by the conditioned medium derived from damaged cells. Moreover, immunodepletion of IL-6 from the conditioned medium abolished reprogramming. Having established that senescence promotes reprogramming, we studied whether tissue injury leading to senescence has a positive effect on OSKM-driven reprogramming. In particular, we show that bleomycin-induced tissue damage strongly promotes reprogramming in the lung. Finally, aging, which is associated with higher levels of cellular senescence, also favors OSKM-driven reprogramming both in progeric and in physiologically aged mice. CONCLUSION The expression of OSKM in vivo triggers two different cellular outcomes: reprogramming in a small fraction of cells, and damage and senescence in many other cells. There is a strong positive association between these two processes, due to the fact that cellular senescence creates a tissue context that favors OSKM-driven reprogramming in neighboring cells. The positive effect of senescence on reprogramming is mediated by secreted factors, of which IL-6 is a key player. This also applies to tissue injury and aging, where there is an accumulation of senescent cells that send signals to surrounding cells to promote OSKM-driven dedifferentiation and reprogramming. A similar conceptual interplay may occur in physiological conditions, where damage-triggered senescence could induce cell dedifferentiation to promote tissue repair. Interplay between cellular senescence and OSKM-driven reprogramming. Expression of OSKM in vivo, apart from inducing the reprogramming of a small population of cells, also induces damage and senescence in many other cells. Senescent cells release factors that promote the reprogramming of neighboring cells, with IL-6 being a critical mediator. Tissue injury and aging, through the accumulation of senescent cells, favor in vivo reprogramming. Reprogramming of differentiated cells into pluripotent cells can occur in vivo, but the mechanisms involved remain to be elucidated. Senescence is a cellular response to damage, characterized by abundant production of cytokines and other secreted factors that, together with the recruitment of inflammatory cells, result in tissue remodeling. Here, we show that in vivo expression of the reprogramming factors OCT4, SOX2, KLF4, and cMYC (OSKM) in mice leads to senescence and reprogramming, both coexisting in close proximity. Genetic and pharmacological analyses indicate that OSKM-induced senescence requires the Ink4a/Arf locus and, through the production of the cytokine interleukin-6, creates a permissive tissue environment for in vivo reprogramming. Biological conditions linked to senescence, such as tissue injury or aging, favor in vivo reprogramming by OSKM. These observations may be relevant for tissue repair.

Biocompatibility, Inflammatory Response, and Recannalization Characteristics of Nonradioactive Resin Microspheres: Histological Findings

Intra-arterial radiotherapy with yttrium-90 microspheres (radioembolization) is a therapeutic procedure exclusively applied to the liver that allows the direct delivery of high-dose radiation to liver tumors, by means of endovascular catheters, selectively placed within the tumor vasculature. The aim of the study was to describe the distribution of spheres within the precapillaries, inflammatory response, and recannalization characteristics after embolization with nonradioactive resin microspheres in the kidney and liver. We performed a partial embolization of the liver and kidney vessels in nine white pigs. The left renal and left hepatic arteries were catheterized and filled with nonradioactive resin microspheres. Embolization was defined as the initiation of near-stasis of blood flow, rather than total occlusion of the vessels. The hepatic circulation was not isolated so that the effects of reflux of microspheres into stomach could be observed. Animals were sacrificed at 48xa0h, 4xa0weeks, and 8xa0weeks, and tissue samples from the kidney, liver, lung, and stomach evaluated. Microscopic evaluation revealed clusters of 10–30 microspheres (15–30xa0μm in diameter) in the small vessels of the kidney (the arciform arteries, vasa recti, and glomerular afferent vessels) and liver. Aggregates were associated with focal ischemia and mild vascular wall damage. Occlusion of the small vessels was associated with a mild perivascular inflammatory reaction. After filling of the left hepatic artery with microspheres, there was some evidence of arteriovenous shunting into the lungs, and one case of cholecystitis and one case of marked gastritis and ulceration at the site of arterial occlusion due to the presence of clusters of microspheres. Beyond 48xa0h, microspheres were progressively integrated into the vascular wall by phagocytosis and the lumen recannalized. Eight-week evaluation found that the perivascular inflammatory reaction was mild. Liver cell damage, bile duct injury, and portal space fibrosis were not observed. In conclusion, resin microspheres (15–30xa0μm diameter) trigger virtually no inflammatory response in target tissues (liver and kidney). Clusters rather than individual microspheres were associated with a mild to moderate perivascular inflammatory reaction. There was no evidence of either a prolonged inflammatory reaction or fibrosis in the liver parenchyma following recannalization.

Telomerase expression confers cardioprotection in the adult mouse heart after acute myocardial infarction

Coronary heart disease is one of the main causes of death in the developed world, and treatment success remains modest, with high mortality rates within 1 year after myocardial infarction (MI). Thus, new therapeutic targets and effective treatments are necessary. Short telomeres are risk factors for age-associated diseases, including heart disease. Here we address the potential of telomerase (Tert) activation in prevention of heart failure after MI in adult mice. We use adeno-associated viruses for cardiac-specific Tert expression. We find that upon MI, hearts expressing Tert show attenuated cardiac dilation, improved ventricular function and smaller infarct scars concomitant with increased mouse survival by 17% compared with controls. Furthermore, Tert treatment results in elongated telomeres, increased numbers of Ki67 and pH3-positive cardiomyocytes and a gene expression switch towards a regeneration signature of neonatal mice. Our work suggests telomerase activation could be a therapeutic strategy to prevent heart failure after MI.

Comparative study of four different spherical embolic particles in an animal model: a morphologic and histologic evaluation.

PURPOSEnTo perform a study in a porcine model comparing four different spherical embolic particles in terms of postembolization patency, deformation, and potential for recanalization, with a focus on a relatively new agent--HepaSphere.nnnMATERIALS AND METHODSnPartial embolization of both kidneys was performed in 18 pigs. Nine animals were sacrificed at 48 hours and nine at 4 weeks. In the same animal, the right kidney was embolized with HepaSphere particles (dry size, 50-100 microm; presumed final size, 200-300 microm), and the left kidney was alternatively embolized with EmboSphere (100-300 microm), Contour (150-350 microm), or Bead Block (150-350 microm) particles. The authors analyzed the size, deformation, and number of particles in each vessel, their morphologic characteristics, and recanalization.nnnRESULTSnParticle sizes and deformation (1,096 particles) were as follows: HepaSphere, 225.3 microm +/- 67 and 26% +/- 19.7, respectively; EmboSphere, 132.9 microm +/- 36 and 18.1% +/- 14.2; Bead Block, 108.1 microm +/- 38 and 16.5% +/- 13.9; and Contour, 240.8 microm +/- 135 and 55.5% +/- 33. HepaSphere and Bead Block particles were distally located, and EmboSphere and Contour particles were located more proximally. EmboSphere and Bead Block particles were round, HepaSphere particles were round and/or ovoid, and Contour particles had an amorphous aspect. EmboSphere particles had a higher tendency to aggregate. No recanalization was seen with HepaSphere particles, and variable recanalization was observed with the others.nnnCONCLUSIONSnDespite similar initial morphologic characteristics, the performance of the agents tested in this study differed in terms of final size, shape, deformation, and luminal recanalization. These differences have potential clinical relevance, and the knowledge of the differing embolic performance may be helpful in choosing agents for specific therapeutic purposes.

Elucidating sources and roles of Granzymes A and B during bacterial infection and sepsis

During bacterial sepsis, proinflammatory cytokines contribute to multiorgan failure and death in a process regulated in part by cytolytic cell granzymes. When challenged with a sublethal dose of the identified mouse pathogen Brucella microti, wild-type (WT) and granzyme A (gzmA)(-/-) mice eliminate the organism from liver and spleen in 2 or 3 weeks, whereas the bacteria persist in mice lacking perforin or granzyme B as well as in mice depleted of Tc cells. In comparison, after a fatal challenge, only gzmA(-/-) mice exhibit increased survival, which correlated with reduced proinflammatory cytokines. Depletion of natural killer (NK) cells protects WT mice from sepsis without influencing bacterial clearance and the transfer of WT, but not gzmA(-/-) NK, cells into gzmA(-/-) recipients restores the susceptibility to sepsis. Therefore, infection-related pathology, but not bacterial clearance, appears to require gzmA, suggesting the protease may be a therapeutic target for the prevention of bacterial sepsis without affecting immune control of the pathogen.

Attenuated Mycobacterium tuberculosis SO2 Vaccine Candidate Is Unable to Induce Cell Death

It has been proposed that Mycobacterium tuberculosis virulent strains inhibit apoptosis and trigger cell death by necrosis of host macrophages to evade innate immunity, while non-virulent strains induce typical apoptosis activating a protective host response. As part of the characterization of a novel tuberculosis vaccine candidate, the M. tuberculosis phoP mutant SO2, we sought to evaluate its potential to induce host cell death. The parental M. tuberculosis MT103 strain and the current vaccine against tuberculosis Bacillus Calmette-Guérin (BCG) were used as comparators in mouse models in vitro and in vivo. Our data reveal that attenuated SO2 was unable to induce apoptotic events neither in mouse macrophages in vitro nor during lung infection in vivo. In contrast, virulent MT103 triggers typical apoptotic events with phosphatidylserine exposure, caspase-3 activation and nuclear condensation and fragmentation. BCG strain behaved like SO2 and did not induce apoptosis. A clonogenic survival assay confirmed that viability of BCG- or SO2-infected macrophages was unaffected. Our results discard apoptosis as the protective mechanism induced by SO2 vaccine and provide evidence for positive correlation between classical apoptosis induction and virulent strains, suggesting apoptosis as a possible virulence determinant during M. tuberculosis infection.

Jagunal homolog 1 is a critical regulator of neutrophil function in fungal host defense

Neutrophils are key innate immune effector cells that are essential to fighting bacterial and fungal pathogens. Here we report that mice carrying a hematopoietic lineage–specific deletion of Jagn1 (encoding Jagunal homolog 1) cannot mount an efficient neutrophil-dependent immune response to the human fungal pathogen Candida albicans. Global glycobiome analysis identified marked alterations in the glycosylation of proteins involved in cell adhesion and cytotoxicity in Jagn1-deficient neutrophils. Functional analysis confirmed marked defects in neutrophil migration in response to Candida albicans infection and impaired formation of cytotoxic granules, as well as defective myeloperoxidase release and killing of Candida albicans. Treatment with granulocyte/macrophage colony-stimulating factor (GM-CSF) protected mutant mice from increased weight loss and accelerated mortality after Candida albicans challenge. Notably, GM-CSF also restored the defective fungicidal activity of bone marrow cells from humans with JAGN1 mutations. These data directly identify Jagn1 (JAGN1 in humans) as a new regulator of neutrophil function in microbial pathogenesis and uncover a potential treatment option for humans.

Aurora B Overexpression Causes Aneuploidy and p21Cip1 Repression during Tumor Development

ABSTRACT Aurora kinase B, one of the three members of the mammalian Aurora kinase family, is the catalytic component of the chromosomal passenger complex, an essential regulator of chromosome segregation in mitosis. Aurora B is overexpressed in human tumors although whether this kinase may function as an oncogene in vivo is not established. Here, we report a new mouse model in which expression of the endogenous Aurkb locus can be induced in vitro and in vivo. Overexpression of Aurora B in cultured cells induces defective chromosome segregation and aneuploidy. Long-term overexpression of Aurora B in vivo results in aneuploidy and the development of multiple spontaneous tumors in adult mice, including a high incidence of lymphomas. Overexpression of Aurora B also results in a reduced DNA damage response and decreased levels of the p53 target p21Cip1 in vitro and in vivo, in line with an inverse correlation between Aurora B and p21Cip1 expression in human leukemias. Thus, overexpression of Aurora B may contribute to tumor formation not only by inducing chromosomal instability but also by suppressing the function of the cell cycle inhibitor p21Cip1.

MMP‐10 Is Required for Efficient Muscle Regeneration in Mouse Models of Injury and Muscular Dystrophy

Matrix metalloproteinases (MMPs), a family of endopeptidases that are involved in the degradation of extracellular matrix components, have been implicated in skeletal muscle regeneration. Among the MMPs, MMP‐2 and MMP‐9 are upregulated in Duchenne muscular dystrophy (DMD), a fatal X‐linked muscle disorder. However, inhibition or overexpression of specific MMPs in a mouse model of DMD (mdx) has yielded mixed results regarding disease progression, depending on the MMP studied. Here, we have examined the role of MMP‐10 in muscle regeneration during injury and muscular dystrophy. We found that skeletal muscle increases MMP‐10 protein expression in response to damage (notexin) or disease (mdx mice), suggesting its role in muscle regeneration. In addition, we found that MMP‐10‐deficient muscles displayed impaired recruitment of endothelial cells, reduced levels of extracellular matrix proteins, diminished collagen deposition, and decreased fiber size, which collectively contributed to delayed muscle regeneration after injury. Also, MMP‐10 knockout in mdx mice led to a deteriorated dystrophic phenotype. Moreover, MMP‐10 mRNA silencing in injured muscles (wild‐type and mdx) reduced muscle regeneration, while addition of recombinant human MMP‐10 accelerated muscle repair, suggesting that MMP‐10 is required for efficient muscle regeneration. Furthermore, our data suggest that MMP‐10‐mediated muscle repair is associated with VEGF/Akt signaling. Thus, our findings indicate that MMP‐10 is critical for skeletal muscle maintenance and regeneration during injury and disease. Stem Cells 2014;32:447–461

Course of Infection with the Emergent Pathogen Brucella microti in Immunocompromised Mice

ABSTRACT A new Brucella species, Brucella microti, has been isolated from wild rodents and found to be pathogenic in mice. The biological relevance of this new mouse pathogen is clear, as it allows us to study Brucella infection in a species-specific model. The course of infection in wild-type (wt) and immunodeficient mice that lack B (Jh), T and B (SCID), or T, B, and NK (SCID.Beige) cells was analyzed over 3 weeks. wt mice completely cleared bacteria from the liver and spleen after that time. However, SCID mice showed a much higher bacterial load in the spleen and liver than wt and Jh mice after 1 week and maintained the same level during the next 2 weeks. All mice tested survived for the 3 weeks. In contrast, the bacterial levels in mice that lacked NK cell activity progressively increased and these mice succumbed to infection after 16 to 18 days. Histopathology analysis of infected mice showed extensive areas of necrotic tissue and thrombosis in liver after 1 week in all infected SCID.Beige mice but were not seen in either SCID or wt animals. These processes were dramatically increased after 21 days, corresponding with the death of SCID.Beige animals. Our results indicate that T and/or B cells are required for the control of infection with the mouse pathogen Brucella microti in liver and spleen but that NK cells are crucial for survival in the absence of B and T cells. In addition, they suggest that controlled granuloma formation is critical to clear this type of infection in wt mice.