Tom R. Phillips

Neurological Abnormalities Associated with Feline Immunodeficiency Virus Infection

Specific pathogen-free cats were infected with the Maryland strain of FIV (FIV-MD) for the purpose of assessing the effects of FIV infection on the central nervous system (CNS). Two separate studies were performed, involving a total of 13 infected cats and six age-matched, sham-inoculated controls. All animals infected with FIV-MD seroconverted by 8 weeks post-infection and virus was recovered from peripheral blood mononuclear cells of all infected cats. All of the infected animals had lower absolute CD4+ cells counts and decreased CD4+/CD8+ ratios. Virus was recovered from the cerebrospinal fluid (CSF) of certain infected individuals, and antiviral antibody and pleocytosis were evident in the CSF of the majority of infected cats. Additionally, virus was recovered from tissue explants from the cerebellum, midbrain and brainstem of one sacrificed FIV+ cat. Specific neurological changes included anisocoria, delayed righting reflex and delayed pupillary reflex, as well as delayed visual and auditory evoked potentials, and marked alterations in sleep patterns similar to those reported for human immunodeficiency virus (HIV)-positive individuals. Histological evaluation revealed the presence of perivascular cuffing and glial nodules in FIV-infected cats. These results indicate that FIV causes an acute neurological disease that closely resembles the early neurological effects of HIV infection in humans and should serve well as an animal model for lentivirus-induced CNS disease.

Neurologic dysfunctions caused by a molecular clone of feline immunodeficiency virus, FIV-PPR.

FIV is a lentivirus of domestic cats that causes a spectrum of diseases that is remarkably similar to the clinical syndrome produced by HIV infection in people. Both HIV and FIV has been shown to cause neurologic dysfunction. Specific Pathogen-Free (SPF) cats were placed into one of three groups: FIV-PPR infected; DU-FIV-PPR (a dUTPase mutant of the FIV-PPR clone) infected; or an age-matched control group. In both infected groups, the general clinical signs of infection included lymphadenopathy, oral ulcerations, rough hair coat, and conjuntivitis. Specific neurological changes in the FIV-PPR infected cats included hind limb paresis; delayed righting and pupillary reflexes; behavioral changes; delayed visual and auditory evoked potentials; decreased spinal and peripheral nerve conduction velocities; and marked alterations in sleep patterns. Most of these changes were also observed in the DU-FIV-PPR infected cats. However, these cats tended to have a slightly less severe disease. In this study, we have demonstrated that an infectious molecular clone of FIV closely parallels the disease course of wild type FIV-infected cats. By using a knockout gene mutant of this clone, we were able to demonstrate that the dUTPase gene is not essential for neuropathogenesis. Further use of the FIV-PPR clone should prove useful in determining the essential viral elements that are important in the neuropathogenesis of lentiviral infections.

Feline Immunodeficiency Virus as a Model for Study of Lentivirus Infection of the Central Nervous System

Feline immunodeficiency virus infects the CNS and results in predictable pathophysiology strikingly similar to that seen with HIV-1 infection of humans. The observed pathophysiology is mimicked in several physiologically assessed modalities, further supporting the validity of the feline model. Peripheral and control evoked potential findings and the occurrence of the sleep architecture changes in both cat and human disease provide an intriguing focus for further investigation. Although structurally diverse in an absolute sense, FIV and HIV-1 share basic structural features and commonalities of their life cycle. It is likely that by understanding the common mechanisms by which these lentiviruses influence CNS function, a more complete understanding of the neurological deficits seen in HIV-1 infected patients will be obtained. The cat model is particularly valuable for study of CNS disease, since it allows detailed analyses of events during the acute phase of infection, under circumstances in which the nature and timing of the infection are carefully controlled. The availability of molecular clones for mutational analysis will facilitate mapping of genomic regions critical to the perturbation of CNS function. It is suggested that development of intervention strategies in the cat model will yield treatment modalities directly applicable to HIV-1 infection of humans.

Feline Immunodeficiency Virus as a Model For Development of Molecular Approaches to Intervention Strategies Against Lentivirus Infections

Publisher Summary All model systems have certain limitations, because the conditions of immunological responsiveness and/or drug tolerance and metabolism may differ from those found in humans. However, every model has unique advantages, and each system will yield useful information regarding the treatment at hand. With the spread of the acquired immunodeficiency syndrome (AIDS) epidemic, driven by the spread of the causative agent, human immunodeficiency virus (HIV), it has become necessary to develop model systems relevant to the treatment of lentivirus infections. Nonhuman primates offer valuable systems for study. The most prominent and feasible primate model is the simian immunodeficiency virus (SIV) infection of rhesus macaques. Both HIV-1 and SIV use a common receptor, CD4, and host cell ranges are similar for the two viruses. Therefore, drug approaches that interrupt receptor interactions may be developed, using SIV as a model system. On the other hand, adult macaques have failed as a useful model for testing drug treatments, such as AZT, probably due to the differential metabolism of the drug. The chimpanzee primate model is closer to humans and is more useful in that; these primates are infectable by HIV directly. However, no disease has been observed and it may be that if any disease is caused at all, the latency will be similar to the decade-long time for the development of AIDS in humans. In addition, chimpanzees are an endangered species and expensive to maintain, and are thus impractical for extensive preliminary testing. There are numerous nonprimate lentiviruses that may serve admirably in the development of intervention strategies effective against HIV. The smallest and most easily manipulable natural model is feline immunodeficiency virus (FIV), a lentivirus found associated with a debilitating immunodeficiency syndrome in cats, similar to AIDS associated with HIV infection of humans. The purpose of this chapter is to report the genomic structure of FIV as it is currently known and to compare it with the structure of HIV. It is clear that there is substantial genomic diversity between these two lentiviruses that negates the utility of FIV for certain intervention approaches. However, it is equally clear that the similarities in the life cycle of HIV and FIV, as well as commonalities in particular structural motifs make FIV an attractive model for comparative study.

Methamphetamine and HIV-1: potential interactions and the use of the FIV/cat model

The interaction of methamphetamine with human immunodeficiency virus (HIV), the aetiologic agent of Acquired Immune Deficiency Syndrome (AIDS), has not been thoroughly investigated. However, increasingly, a larger proportion of HIV infected individuals acquire the virus through methamphetamine use or are exposed to this drug during their disease course. In certain populations, there is a convergence of methamphetamine use and HIV-1 infection; yet our understanding of the potential effects that simultaneous exposure to these two agents have on disease progression is extremely limited. Studying the interactions between methamphetamine and lentivirus in people is difficult. To thoroughly understand methamphetamines effects on lentivirus disease progression, an animal model that is both clinically relevant and easily manipulated is essential. In this report, we identified potential problems with methamphetamine abuse in individuals with a concurrent HIV-1 infection, described the Feline Immunodeficiency Virus (FIV)/cat model for HIV-1, and reported our early findings using this modelling system to study the interaction of methamphetamine and lentivirus infections.

Neurotoxic effects of feline immunodeficiency virus, FIV - PPR

FIV is a lentivirus of domestic cats that causes neurologic disorders which are remarkably similar to those found in HIV-1 infected people. Using feline neuron cultures, we investigated the potential of both FIV virus and FIV-Env protein to cause neuronal damage through the excitotoxicity mechanism. The neuron swelling and lactate dehydrogenase (LDH) release assays were used as measures of cellular damage. The effects of FIV Env protein on glutamate receptor mediated increases in intracellular calcium were also examined. We found that FIV virus and FIV-Env protein significantly increased LDH release from the neuron cultures. Additionally, an increase in neuron size was detected in the cultures exposed to the virus, while swelling did not occur with exposure to either saline, denatured virus, or FIV-Env by itself. However, when both 20 microM glutamate and the FIV-PPR Env protein were added to the culture, a significant increase in neuron cell size was observed. The NMDA calcium signals were similar in general form between the control and FIV-PPR Env exposed cultures. However, the FIV - PPR Env protein treated cultures resulted in significant enhancement of the NMDA induced calcium signal. Our results indicate that FIV Env protein (either within the virion or baculovirus expressed) induced neurotoxicity as measured by neuron swelling and LDH release assays and that exposure of feline neurons to FIV Env protein alters the handling of intracellular calcium. These findings help to validate the FIV/cat system as a potential animal model for evaluating therapeutic approaches that target the excitotoxicity mechanisms of lentivirus induced CNS disease.

Intraventricular administration of a FIV-envelope protein induces sleep architecture changes in rats☆

Fifteen adult male Sprague-Dawley rats were implanted with a set of electrodes for standard sleep recordings. A stainless steel cannula was also implanted into the lateral ventricle of these rats. Fifteen additional rats were implanted with a cannula alone. Rats with electrodes were habituated for 3 days or more to the recording environment, then placed into 3 groups (n = 5). One group received saline (i.c.v.), while the other two groups received either the feline immunodeficiency virus envelope glycoprotein (FIV SU-Env) or a fragment of the Epstein-Barr virus envelope glycoprotein (EB gp105). Rats were then recorded for electrographic sleep-wake cycle evaluation for the following 4 h. Core temperature was assessed through a thermistor probe inserted into the rectum, immediately before and 1, 2, 3 and 4 h after the i.c.v. treatment condition. Results demonstrated that compared to saline, FIV SU-Env increased wakefulness and decreased REM sleep throughout the 4 h of recording. Likewise, FIV SU-Env decreased SWS2 for 2 h. In addition, EB gp105 administration elicited minor modifications of the sleep-wake cycle, causing only a transient reduction of REM sleep in the first hour of recording. None of the treatments altered body temperature. These findings strongly support and extend studies in FIV-infected cats in which we have found similar sleep abnormalities. In addition, these results are consistent with the hypothesis that the FIV SU-Env proteins are responsible for these neurological disturbances.(ABSTRACT TRUNCATED AT 250 WORDS)

Cortical neuronal cytoskeletal changes associated with FIV infection

HIV-1 infection is often complicated by central nervous system (CNS) dysfunction. Degenerative neuronal changes as well as neuronal loss have been documented in individuals with AIDS. Feline immunodeficiency virus (FIV) infection of cats provides a model for both the immune and the central nervous system manifestations of HIV infection of humans. In this study we have examined neurons in the frontal cortex of feline immunodeficiency virus-infected cats and controls for immunoreactivity with SMI 32, an antibody recognizing a non-phosphorylated epitope on neurofilaments. We noted a significant increase in the number of immunoreactive pyramidal cells in infected animals compared to controls. The changes seen in the neuronal cytoskeleton as a consequence of the inoculation with FIV were similar to those seen in humans undergoing the normal aging process as well as those suffering from neurological diseases, including Alzheimers and dementia pugilistica. The changes we noted in the feline brain were also similar to that reported in animals with traumatic injuries or with spontaneously occurring or induced motor neuron diseases, suggesting that the increase in reactivity represents a deleterious effect of FIV on the central nervous system.

Escalating morphine exposures followed by withdrawal in feline immunodeficiency virus-infected cats: a model for HIV infection in chronic opiate abusers

Opiate abuse is a risk factor for human immunodeficiency virus (HIV) infection. Because the direct effects of opiates on HIV infection are difficult to determine epidemiologically, animal models of lentivirus infection are relied upon to study the effects of opiates in the absence of confounding factors. Morphine, the predominant metabolite of heroin, is used in most experimental systems examining heroin abuse. In this study, morphine treatment of feline immunodeficiency virus (FIV)-infected cats modeled a typical pattern of escalating drug use interspersed with withdrawals. Plasma cortisol levels were measured for evidence of stress associated with morphine withdrawal. In the morphine-treated cats, cortisol levels peaked at time points corresponding to morphine withdrawal and returned to baseline levels during treatment and several weeks after the final withdrawal. Morphine-treated cats displayed clear behavioral and physical signs of opiate exposure and evidence of withdrawal when the drug was stopped. Morphine-exposed cats did not experience enhanced severity of FIV-related disease; in fact, morphine demonstrated a protective effect on FIV-associated changes in brainstem auditory evoked potentials. Our research suggests that opiate exposure is unlikely to adversely affect the progression of acute lentivirus infection and might be beneficial in controlling associated neurological disease.

Effects of Multiple Acute Morphine Exposures on Feline Immunodeficiency Virus Disease Progression

Drug abuse is a common method of human immunodeficiency virus type 1 transmission, but the role of opiates on lentivirus disease progression is not well understood. The feline immunodeficiency virus (FIV)/cat system was used to model the weekend opiate abuser: the nondependent, nonaddicted, and nontolerant person. Sixteen cats were placed into 4 groups: FIV only, morphine only, morphine/FIV, and controls. Multiple acute morphine exposure did not increase the severity of early lentivirus infection. On the contrary, it delayed or moderated the FIV-induced disease progression. Although the animals were exposed to only 1 injection of morphine per day for 2 consecutive days per week, the morphine-treated FIV-infected animals had a delayed onset of the FIV-induced lymphadenopathy, did not develop or had a significant delay in the FIV-induced effects on brain stem auditory evoked potentials, and demonstrated a trend toward decreased virus load.