Activation of isolated lysosomes by poliovirus-infected cell extracts

DRAM triggers lysosomal membrane permeabilization and cell death in CD4(+) T cells infected with HIV

Productive HIV infection of CD4⁺ T cells leads to a caspase-independent cell death pathway associated with lysosomal membrane permeabilization (LMP) and cathepsin release, resulting in mitochondrial outer membrane permeabilization (MOMP). Herein, we demonstrate that HIV infection induces damage-regulated autophagy modulator (DRAM) expression in a p53-dependent manner. Knocking down the expression of DRAM and p53 genes with specific siRNAs inhibited autophagy and LMP. However, inhibition of Atg5 and Beclin genes that prevents autophagy had a minor effect on LMP and cell death. The knock down of DRAM gene inhibited cytochrome C release, MOMP and cell death. However, knocking down DRAM, we increased viral infection and production. Our study shows for the first time the involvement of DRAM in host-pathogen interactions, which may represent a mechanism of defense via the elimination of infected cells.

Lysosomes are acidic organelles capable of digesting macromolecules and regulating autophagy. In the context of host-pathogen interactions, productive viral infections are associated with lysosome membrane permeabilization (LMP) and programmed cell death (PCD). At a molecular level, the tumor suppressor protein 53 (p53), which is a key player in the detection of DNA damage, acts also as a sensor of pathogen replication. Activation of p53 has been considered to be an altruistic cell suicide mechanism that limits viral infection. Here, we provide new evidence that damage-regulated autophagy modulator (DRAM), a p53 target gene, regulates both LMP and PCD of HIV-infected CD4 T cells. Whereas the inhibition of DRAM or p53 prevents autophagy in infected cells, the inhibition of the autophagy machinery has a minor role in this context. As a consequence, the silencing of DRAM leads to increased HIV viral infection. This is the first report describing the role of DRAM in the context of host-pathogen interaction. Whereas it is to the advantage of the pathogens to preserve their hosts and thus facilitate their multiplication and dissemination, hosts have developed altruistic cellular processes to defend themself and limit the spread of the infectious agent in multicellular organisms. We propose that the ancestral DRAM protein represents a mechanism of self-defense, inducing elimination of infected cells through LMP.

Further studies on a vaccinia virus cytotoxin present in infected cell extracts: identification as surface tubule monomer and possible mode of action

A vaccinia virus-specific cytotoxic protein (3--10 X 10(4) daltons) had previously been detected in extracts of infected HeLa cells. In this study the protein has been shown to be a late gene product and a virion component--almost certainly the monomer of the surface tubules of the vaccinia virion. The relationship of this cytotoxin to a number of early vaccinia-induced cytopathic effects was examined: it was not the mediator of vaccinia-induced early cell rounding, did not inhibit protein or RNA synthesis in cell-free systems or intact cells (after uptake-induction by hypertonic MgSO4), or cause the release of beta-glucuronidase from a crude preparation of HeLa cell lysosomes. Its possible role in vaccinia-induced cell degeneration, late in infection, is discussed.

The lysosomal permeability test modified for toxicity testing with cultured heart endothelioid cells

A modified lysosomal fragility test is described which is suitable for use with cultured cells. The permeability (fragility) of the lysosomal membranes of the cells to the substrate beta-glycerophosphate is measured by assessing the degree of particulate lysosomal straining seen after exposing the cells to the Gomori acid phosphatase staining reaction under carefully controlled conditions. Monolayer cultures of endothelioid cells from the hearts of neonatal rats have been used in all experiments. The time-course of lysosomal straining for cells exposed to various treatments (normal saline, isotonic sucrose, 0.25 m sucrose, distilled water, acetate buffer pH 5.0, cold acetone, neutral formalin, acetic-ethanol, Triton X-100, hydrocortisone, choloroquine and vitamin A) was compared with that of control cells stained under identical conditions. Statistical differences in staining between the test and control cells were determined by the Wilcoxin Signed Rank Test and also by regression analysis following a transformation designed to allow for the saturation character of the reaction. The success of the modified technique depends upon meticulous methodology. It is capable of demonstrating both lysosomal membrane labilization and stabilation, second- and third-stage lysosomal activation, and apparent lysosomal enzyme loss or destruction in situ. The technique also allows the degree of reversible or first-stage lysosomal activation to be subdivided on an almost continous basis and is suitable for investigating the effects of drugs and other agents on the integrity of the lysosome in situ.

Effects of actinomycin D on the cytopathology induced by poliovirus in HEp-2 cells

One possible mechanism of virus-induced cell damage is that the redistributed (released) lysosomal enzymes produce the cytopathic effect during cytolytic types of infections such as poliovirus in HEp-2 cells. To determine if the lysosomal enzyme redistribution and cell damage are host-cell directed, we studied sensitivity of these events to the action of actinomycin D. By the use of actinomycin D at concentrations producing the least toxicity but maximal effectiveness in shuting down cell RNA synthesis, it was shown that the cytopathic effect and enzyme redistribution were not inhibited and, therefore, not directly controlled and induced by the cell genome in response to the virus infection. Evaluation of cytopathic effect by a phase contrast microscopy method detected changes earlier than the erythrocin B uptake method.

Virus replication, cytopathology, and lysosomal enzyme response of mitotic and interphase Hep-2 cells infected with poliovirus

Mitotic Hep-2 cells, selected by the PEL (colloidal silica) density gradient method and held in mitosis with Colcemid, are readily infected by poliovirus type I (Mahoney). They produce and release the same amount of virus as interphase, random-growing cells. In contrast to interphase cells, mitotic cells show no detectable virus-induced cytopathic effect at the light microscopy level and only slight alterations, consisting of small clusters of vacuoles, at the electron microscopy level. Mitotic cells contain the same total amount of lysosomal enzymes per cell as interphase cells, but they display no redistribution of lysosomal enzymes during the virus infection as interphase cells do. This supports the view that lysosomal enzyme redistribution is associated with the cytopathic effect in poliovirus infection but shows that virus synthesis and release is not dependent on either the cytopathic effect or lysosomal enzyme release. The possible reasons for the lack of cytopathic effect in mitotic cells are discussed.

Effect of host cell on distribution of a lysosomal enzyme during virus infection

The time of appearance of a lysosomal enzyme, beta-glucuronidase, in the medium of cells infected with either measles virus or echovirus 6 varied with the host cell system. Replication and release of virus preceded leakage of beta-glucuronidase from green monkey kidney cells. In contrast, extracellular enzyme appeared before replication and release of virus in human amnion cells. Hydrocortisone depressed enzyme leakage but did not retard replication of measles virus or viral-induced cytopathology. The intracellular distribution of beta-glucuronidase in uninfected and measles virus-infected cells was also studied. Measles virus infection altered the position of particulate-bound beta-glucuronidase in linear sucrose gradients prior to substantial release of this enzyme intra- and extracellularly. At early stages in infection, most of the cell-associated virus banded with particulate-bound enzyme in the middle of the gradient. As infection progressed, separation of measles virus infectivity from enzyme activity occurred, and intracellular virus was recovered near the meniscus of sucrose gradients.