An alternative approach to medical genetics based on modern evolutionary biology. Part 2: retroviral symbiosis

Cell type-specific regulation of the pentose phosphate pathway during development and metabolic stress-driven autoimmune diseases: Relevance for inflammatory liver, renal, endocrine, cardiovascular and neurobehavioral comorbidities, carcinogenesis, and aging

The pathogenesis of autoimmunity is incompletely understood which limits the development of effective therapies. New compelling evidence indicates that the pentose phosphate pathway (PPP) profoundly regulate lineage development in the immune system that are influenced by genetic and environmental factors during metabolic stress underlying the development of autoimmunity. The PPP provides two unique metabolites, ribose 5-phosphate for nucleotide biosynthesis in support of cell proliferation and NADPH for protection against oxidative stress. The PPP operates two separate branches, oxidative (OxPPP) and non-oxidative (NOxPPP). While the OxPPP functions in all organisms, the NOxPPP reflects adaptation to niche-specific metabolic requirements. The OxPPP primarily depends on glucose 6-phosphate dehydrogenase (G6PD), whereas transaldolase (TAL) controls the rate and directionality of metabolic flux though the NOxPPP. G6PD is essential for normal development but its partial deficiency protects from malaria. Although men and mice lacking TAL develop normally, they exhibit liver cirrhosis progressing to hepatocellular carcinoma. Mechanistic target of rapamycin-dependent loss of paraoxonase 1 drives autoimmunity and cirrhosis in TAL deficiency, while hepatocarcinogenesis hinges on polyol pathway activation via aldose reductase (AR). Accumulated polyols, such as erythritol, xylitol, and sorbitol, which are commonly used as non-caloric sweeteners, may act as pro-inflammatory oncometabolites under metabolic stress, such as TAL deficiency. The TAL/AR axis is identified as a checkpoint of pathogenesis and target for treatment of metabolic stress-driven systemic autoimmunity with relevance for inflammatory liver, renal and cardiovascular disorders, diabetes, carcinogenesis, and aging.

[These viruses that inhabit and visit us: The human virome]

Recent advances in new sequencing technologies have opened the way to the deciphering of human virome. So far, human virome is defined as the complete list of viruses found in human body. Those viruses could be endogenous, prokaryotic, archaeal and eukaryotic. In addition, each compartment of the human body constitutes a different microenvironment with its own virome. Viral infections can be categorized according to the outcome of the acute phase and until recently, only symptomatic and pathological infections were studied. It is now well established that a healthy person has an extremely diverse virome. This review summarizes the current state of our knowledge and also proposes another classification of the human virome based on principles of ecology.

Short communication: expression profiles of endogenous retroviral envelopes in Macaca mulatta (rhesus monkey)

Endogenous retroviruses (ERVs), which are footprints of ancient germline infections, were inserted into the genome during the early stages of primate evolution. Human endogenous retroviruses (HERVs) occupy approximately 8% of the human genome. Although most ERV genes are defective, with large deletions, stop codons, and frameshifts in their open reading frames (ORFs), some full-length sequences containing long ORFs are expressed in several tissues and cancers. Several envelope glycoproteins that are encoded by env genes have retained some characteristics of their ancestral infectious viruses. These glycoproteins play essential physiological roles in the organs in which they are expressed. Previous studies have demonstrated the expression of ERV env at the mRNA level in cells and tissues rather than at the protein level, which is more difficult to detect. However, it is not known whether Env is functionally conserved in primates. To understand the possible role of Env in primates, we examined the expression of the env genes of four ERVs (ERV-R, -K, -W, and -FRD) at the protein as well as mRNA levels in various tissues of the rhesus monkey. The ERV env gene products were observed at moderate to high levels in each tissue that was examined and showed tissue-specific expression patterns. Our data suggest a biologically important role for retroviral proteins in healthy tissues of the rhesus monkey.

Detection of the human endogenous retrovirus ERV3-encoded Env-protein in human tissues using antibody-based proteomics

OBJECTIVES

There is growing evidence to suggest that human endogenous retroviruses (HERVs) have contributed to human evolution, being expressed in development, normal physiology and disease. A key difficulty in the scientific evaluation of this potential viral contribution is the accurate demonstration of virally expressed protein in specific human cells and tissues. In this study, we have adopted the endogenous retrovirus, ERV3, as our test model in developing a reliable high-capacity methodology for the expression of such endogenous retrovirus-coded protein.

DESIGN

Two affinity-purified polyclonal antibodies to ERV3 Env-encoded protein were generated to detect the corresponding protein expression pattern in specific human cells, tissues and organs.

PARTICIPANTS

Sampling included normal tissues from 144 individuals ranging from childhood to old age. This included more than forty different tissues and organs and some 216 different cancer tissues representing the twenty commonest forms of human cancer.

SETTING

The Rudbeck Laboratory, Uppsala University and Uppsala University Hospital, Uppsala, Sweden.

MAIN OUTCOME MEASURES

The potential expression at likely physiological level of the ERV3Env encoded protein in a wide range of human cells, tissues and organs.

RESULTS

We found that ERV3 encoded Env protein is expressed at substantive levels in placenta, testis, adrenal gland, corpus luteum, Fallopian tubes, sebaceous glands, astrocytes, bronchial epithelium and the ducts of the salivary glands. Substantive expression was also seen in a variety of epithelial cells as well as cells known to undergo fusion in inflammation and in normal physiology, including fused macrophages, myocardium and striated muscle. This contrasted strongly with the low levels expressed in other tissues types. These findings suggest that this virus plays a significant role in human physiology and may also play a possible role in disease.

CONCLUSION

This technique can now be extended to the study of other HERV genomes within the human chromosomes that may have contributed to human evolution, physiology and disease.

Human endogenous retroviruses in multiple sclerosis: potential for novel neuro-pharmacological research

There is growing evidence that the env genes of two or more human endogenous retroviruses (HERVs) of the W family are contributing to the inflammatory processes, and thus to the pathogenesis, of multiple sclerosis (MS). Increasing understanding of the human endogenous retroviral locus, ERVWE1, and the putative multiple sclerosis associated retrovirus, or MSRV, and in particular of the HERV-W env sequences associated with these, offers the potential of new lines of pharmacological research that might assist diagnosis, prognosis and therapy of multiple sclerosis.

Melanoma, Darwinian medicine and the inner world

INTRODUCTION

A diverse range of human diseases, including allergy, asthma, autoimmune disease, cancer and chronic neurologic diseases, notably multiple sclerosis and endogenous depression, is becoming more prevalent in industrialized countries. It has been postulated that environmental factors associated with improved standards of hygiene play a leading role in this process since the immune system seems to need extrinsic challenges for its proper maturation.

THE INNER WORLD

An added dimension has now emerged--the impact on disease of the inner world, principally the numerous endogenous retroviruses (HERVs) within the human genome. Taking melanoma as an example, we propose a framework for understanding how a complex infectious and immunological background can induce or inhibit expression of a HERV-related disease process. The central role of a failure to induce or to maintain certain populations of self-specific CD8(+) T-cells mediating immune surveillance, the expression of HERV-encoded peptides on affected cells and pathological mechanisms directly attributable to HERV proteins are discussed.

CONCLUSIONS

The presented concepts explain events preceding the clinical manifestation of diseases by several years and provide a rationale for the use of currently available vaccines to protect against certain HERV-induced diseases, especially melanoma. Criteria for establishing the causal role of HERVs in a given disease are proposed.

Widespread horizontal gene transfer from double-stranded RNA viruses to eukaryotic nuclear genomes

Horizontal gene transfer commonly occurs from cells to viruses but rarely occurs from viruses to their host cells, with the exception of retroviruses and some DNA viruses. However, extensive sequence similarity searches in public genome databases for various organisms showed that the capsid protein and RNA-dependent RNA polymerase genes from totiviruses and partitiviruses have widespread homologs in the nuclear genomes of eukaryotic organisms, including plants, arthropods, fungi, nematodes, and protozoa. PCR amplification and sequencing as well as comparative evidence of junction coverage between virus and host sequences support the conclusion that these viral homologs are real and occur in eukaryotic genomes. Sequence comparison and phylogenetic analysis suggest that these genes were likely transferred horizontally from viruses to eukaryotic genomes. Furthermore, we present evidence showing that some of the transferred genes are conserved and expressed in eukaryotic organisms and suggesting that these viral genes are also functional in the recipient genomes. Our findings imply that horizontal transfer of double-stranded RNA viral genes is widespread among eukaryotes and may give rise to functionally important new genes, thus entailing that RNA viruses may play significant roles in the evolution of eukaryotes.