The lymphocyte cell coat is a labile structure, and the treatment of cells may lead to the loss of its components 151617181920. The cell coat plays an important role in lymphocyte functions including homing, cell mediated immunity, electrophoretic properties and antigen expression 21; cell surface proteins are thought to be involved in cell propagation and differentiation 18. After treatment with β-glucosidase 22, sialidase 2324 and trypsin 25, lymphocytes lose their homing abilities. Cytotoxic lymphocytes transiently lose their cytotoxic ability after a brief papain treatment 26. Lysis of the cell coat suppresses cell-mediated immunity 272829. Treatment by glycosidases including neuraminidase affects the bodily distribution of lymphocytes 2324 and demonstrates alterations in their antigenicity 3031323334. Treatment with trypsin and neuraminidase reversibly eliminates the mitogenic response of lymphocytes 3536. The cell coat on thymocytes is significantly thicker than on splenic lymphocytes, 20 suggesting a role for the cell coat in T cell function. The cell coat of the lymphocyte cell membrane has been characterized using various stains 151617, 373839. These investigations found high acid mucopolysaccharide content with a significant number of acidic amino sugar end groups.

Cancer cells also exhibit an exterior cell surface coat 404142434445. The similarities between the cell coat of normal and leukemic lymphocytes have been investigated 3941. Pathological lymphocytes (CLL) have a uniformity of staining similar to their normal counterparts, with some differences observed with cationic stains that could be due to a decrease in the sialoprotein of the cell coat of CLL cells. With some similarity to lymphocytes, the tumor cell coat has been suggested to play a role in cell contact and adhesion, cell recognition 44, as well as the capacity to metastasize 46.

The tumor cell coat is also sensitive to neuraminidase 474849 and can rapidly re-grow following treatment with the enzyme 50. The enzyme treatment also changes the immunological properties of tumor cells. Trypsin and EDTA removes the tumor cell coat 51. The cell coat is involved in the mechanism by which tumor cells escape cellular immune attack 45525354. The degradation of the cell coat by brief hyaluronidase treatment of glioma cells sensitizes them to cytotoxic lymphocyte attack 5253. Although normal human glial cells also produce hyaluronic acid, glioma lines produced significantly more. Hyaluronidase-sensitive coats have been found on a variety of murine sarcoma and carcinoma cell lines 54. It appears that a mucopolysaccharide coat on tumor cells impedes the successful use of immunotherapy. It was demonstrated that the displacement of the tumor cell coat by charge-functionalized lipids or polycationic substances leads to tumor cell apoptosis and tumor destruction 455556.

It is demonstrated that the cell coat of lymphocytes and tumor cells are functionally significant. The degradation/removal of cell coat significantly impacts the functionality of both tumor cells and lymphocytes; therefore, tumor cell isolation methods could alter the functionality of isolated cells. In other words, with the loss of the cell coat, lymphocytes lose fundamental functions, i.e., cannot attack target cells, while tumor cells also lose cell contact and adhesive properties, as well as the ability to metastasize. In addition, tumor cells become sensitive to apoptosis.

The activation of coagulation occurs during tissue injury as well as in various pathologies. Infection leads to an inflammatory reaction as well as the activation of coagulation, as there is a crosstalk between these functions 575859. Blood coagulation components can inhibit or amplify the inflammatory response. Blood clotting is initiated when pathogenic components such as endotoxin or inflammatory cytokines induce the synthesis of tissue factor on leukocytes 60. The coagulation cascade is subsequently triggered. The formation of negatively charged membrane phospholipid surfaces amplifies the coagulation reaction 61. Natural anticoagulant pathways such as the protein C anticoagulant pathway limit the coagulation process, thereby suppressing the inflammatory response including reducing inflammatory cytokine secretion 62, decreasing NF-κB signaling 63, minimizing leukocyte chemotaxis 64 and endothelial cell interactions 65, and suppressing apoptosis 66.

Platelets are also involved in the link between inflammation and coagulation. Inflammatory cytokines such as IL-6 or IL-8 increase platelet production, and such platelets are more thrombogenic 67. In addition, the platelets release the CD40L protein, a potent proinflammatory mediator, which subsequently induces tissue factor synthesis 6869 and amplifies the secretion of proinflammatory cytokines 7071. This in turn leads to a progressive cycle that ultimately can produce severe vascular and organ injury.

In 1865, Trousseau first described a cancer-associated condition now called migratory thrombophlebitis in which a spontaneous coagulation of the blood occurs in the absence of inflammatory reactions 72. It manifests as migratory thrombosis in the superficial veins of the chest wall and arms, but it can occur in other sites as well. This condition is a variant of venous thromboembolism. Thrombosis is a frequent complication of malignancy, and thromboembolic death is the second leading cause of mortality in cancer 7374. Malignant cells interact with the blood coagulation system by releasing procoagulant and fibrinolytic substances and inflammatory cytokines 7576777879808182838485. In addition, direct interaction with endothelial cells, monocytes/macrophages, and platelets also leads to localized clotting activation 858687. Similar to normal activated inflammatory cells, malignant cells release tissue factor 757677 which promotes the formation of fibrin deposits in the tumor cell microenvironment 888990.

The fibrin gel matrix along with other connective tissue components form the basis for the tumor stroma, a matrix in which tumor cells are dispersed and which provides the vascular supply as well as a barrier against rejection by the cellular immune system 89. The tumor stroma shares properties in common with the temporary stroma of a healing wound 91. Similar to the fibrin coating on macrophages 92, the observed fibrin coating of tumor cells is involved in the mechanism by which tumor cells escape destruction by NK cells 9394. Histological evidence suggests that inflammatory lymphocytes are confined to the tumor-host interface, and do no not significantly penetrate the tumor 8995. Malignant cells secrete inflammatory cytokines such as TNF-α and IL-1β that downregulate the anticoagulant system of vascular endothelial cells 9697. The secretion of IL-8 promotes new blood vessel formation, 98 and the fibrin deposited around tumor cells facilitates angiogenesis 99100101.

Tumor cells attach to the vascular endothelium and promote the adhesion of leukocytes and platelets 102103104105. Monocytes and macrophages also home in on vascular surfaces due to inflammatory stimuli 106107108. In response to inflammatory molecules, complement, lymphokines and immune complexes, these cells subsequently secrete procoagulant tissue factor; tumor-associated macrophages express significantly higher levels of tissue factor than control cells 109110. These macrophages also increase their fibrinolytic enzyme production 111.

Both human and animal cancer causes platelet aggregation in vitro and in vivo 112113114. The ability of tumor cells to aggregate platelets and secrete plasminogen activator correlates with their metastatic potential 115. Indeed, thrombocytopenia reduces the metastases of tumors 116117 as do compounds capable of reducing platelet aggregation 117118119120121122123124125. These include aspirin, prostaglandins and other nonsteroidal (NSAID) anti-inflammatory drugs. A reduced risk of fatal colon cancer has been observed among aspirin users 120121122. Administration of heparin and fibrinolysin also reduces the incidence of experimental metastases 126127128, while the administration of anti-fibrinolytic agents increases their incidence 129130.

Cancer treatment by surgery, cytotoxic antineoplastic drugs and hormonal therapy all contribute to the hypercoagulable state and risk factors for thromboembolism in cancer patients 131132. The risk of fatal pulmonary embolism increases four-fold after surgery in cancer patients 133134. Chemotherapy drugs including cysplatin, mytomicin C and tamoxifen as well as high-dose and multi-drug regimes increase the risk of thrombotic complications 135136137138139. Prophylactic treatment with warfarin reduces this risk (140). The use of hematopoietic growth factors subsequent to chemotherapy was shown to induce thrombosis in breast cancer patients 141142. Venous thrombosis could also be a marker for an otherwise asymptomatic cancer 143144.

Similarly to a normal inflammatory reaction, activation of coagulation takes place in cancer. The events of tumor stroma development are comparable to wound healing 91 and it is possible that tumor formation may be associated with defective wound healing initiated by an inflammatory reaction due to infection and/or tissue injury. Therefore, we believe it is important to investigate potential links between infection, inflammation and cellular immune response in searching for the origins of the cancer cell.

The etiological role of infectious agents has been indicated in various cancers. In 100 cases of human leukemia, Mycoplasma, Salmonella, Micropolyspora, Mycobacterium, Absidia, pseudorabies virus and adenovirus antigens were commonly detected in the patient's sera 145. Hepatotropic viruses (hepatitis B and C) cause hepatic necrosis followed by hepatocellular, B cell and gastric malignancies 146147148149. Antiviral therapy of hepatitis C infection led to the regression of virus-associated B cell lymphoma 150. Adenoviral infection has been associated with childhood leukemia 151 and cytomegalovirus infection with testicular cancer 152. Helicobacter pylori infection is widespread in the population (an estimated 40–80% infected) and is linked to gastric cancer and mucosa-associated lymphoid tissue (MALT) lymphoma 153154. A reversal of lymphoma-induced neutropenia has been observed with the eradication of H. pylori infection 154. Simian virus 40 (SV40) is associated with human brain cancers and non-Hodgkin's lymphoma 155. Ocular adnexal lymphoma is linked to Chlamydia psittaci infection, and the reversal of lymphoma was observed with pathogen-eradicating antibiotic therapy 156. The list continues: Cervical intraepithelial neoplasia (CIN) is associated with human papilloma virus (HPV) infection with a co-etiological presence of chronic bacterial cervicitis 157158159. Mycoplasma and HPV association was found to be dominating. The role of mycoplasma in the dysplasia of the uterine cervix and development of CIN has also been demonstrated 160.

Mycoplasmas are particularly interesting due to their widespread presence in the human population. Although many mycoplasmas are not directly pathogenic in humans, they are associated with many diseases 161162163164165. Mycoplasmas have co-leukemogenic activity 166167168 and are found to increase tumor cell invasiveness 169. In approximately half of the examined cases, mycoplasma DNA was present in ovarian and gastric carcinoma specimens 170171. In gastric, lung, esophageal, breast and colon cancers as well as glioma specimens, Mycoplasma hyorhinis was detected in about 50% of the cases 172. Mycoplasmas are known to cause chromosomal changes 173. Mixed Mycoplasma pneumoniae and influenza virus infection induced lung cancer in an animal model 174. The direct role of the AIDS-associated Mycoplasma fermentans and Mycoplasma penetrans in oncogenesis has been investigated 175. These mycoplasma strains induced gradual malignant transformations that eventually became irreversible. Besides its direct oncogenic potential, Mycoplasma fermentans was found to exhibit a unique cytocidal effect on the undifferentiated myelomonocytic lineage, but not on differentiated myelomonocytic cells 176. The depletion of immature myelomonocytic cells likely contributes to the functional immunodeficiency present in cancer patients.

In response to pathogens, the host mounts a protective inflammatory response. Immune cells migrate to the area of infection and produce inflammatory messengers called cytokines. Initially, cells of the innate immune system (macrophages, neutrophils, NK cells) become involved, followed by the activation of cells of the adaptive immune system. These include antigen-presenting cells (APCs), T and B cells, which play an important role in propagating the inflammatory response. T cell inflammation plays a major role in antitumor immune responses. Key regulators of T cell-mediated response are the T helper (Th) cells that secrete the cytokines orchestrating this response. The two subtypes Th1 and Th2 cells produce cytokines stimulating cellular and humoral immune responses.

Intracellular pathogens (e.g., viruses, mycoplasmas) use the Toll-like receptor (TLR) signaling mechanism to escape host defenses 177. Pathogen-associated molecular patterns on the surface of mycoplasmas engage TLRs 1, 2, and 6 on the surface of APCs that lead to a Th2-type polarization of the immune response and the secretion of IL-10, IL-4, IL-5 and IL-13 178179180. These cytokines are antagonistic to Th1 type cytokines (TNF-α, IL-2, IFN-γ, IL-6, IL-12); excessive production of either type of cytokine upsets the homeostatic balance needed to maintain a proper mix of cellular and humoral immune responses. Utilizing this mechanism, mycoplasmas suppress cell-mediated immunity, which allows them to persist and predispose the host for colonization by other pathogens. The observation that leukemia patients were colonized by over half a dozen pathogens besides mycoplasmas 145 suggests that suppression of the cellular immune system provides a fertile ground for a variety of pathologies.

Besides regulating innate and adaptive immune responses, cytokines are involved in cell growth and differentiation. Normally, the secretion of cytokines is of short radius and limited duration, typically regulating self or adjacent cell functions. The activity of cytokines is tightly regulated, and there is evidence that cytokines contribute to inflammatory autoimmune diseases 181182183184 and malignancies. Similarly to activated T cells, various tumor cells secrete immune response-polarizing cytokines (IL-10, IL-6, IL-8, IL-13, TGF-β) serving as autocrine and/or paracrine growth factors for the cancer 185186187188189190191192193194195196197198199. The progression of the disease and patient survival was correlated with increasing levels of cytokine secretion 200. This secretion is frequently constitutive, leading to elevated serum levels of cytokines in malignancies including melanoma, non-small cell lung carcinoma, renal cell carcinoma and bladder carcinoma 186187188189190201. In addition, tumor cells can induce IL-10 in the tumor environment 191. IL-10, the most potent Th2 polarizing cytokine, suppresses the tumoricidal activity of macrophages 202, blocks presentation of tumor antigens to professional APCs 203204205, and inhibits tumor-specific cytotoxic T cells 206. However, in cancers both cellular and humoral immune response may be depressed, as in the absence of IL-4 production IL-10 secretion alone cannot induce a Th2-type response.

It appears that the immune response becomes distorted at multiple levels during the development of cancer. First, infectious agents may act in concert to subvert cellular immunity, thereby upsetting the homeostatic balance of a proper mix of cellular and humoral immune response. This leads to an aberrant cytokine-signaling that results in depressed apoptosis and excessive proliferation 207208. Cytokines seem to be the key substance of apoptosis of leukemic cells 207. Abnormal inflammatory cytokine secretion by tumor cells reinforces the existing imbalances and thus promotes disease progression. Similarly to T cells, cancer cells use inflammatory cytokines as autocrine and paracrine growth factors, suggesting a functional relationship between cancer cells and cells of the immune system.

Several lines of evidence suggest a direct relationship between infection, autoimmunity and cancer. Hepatitis B and C viruses are involved in an autoimmune condition that precedes the development of hepatocellular carcinoma 209. Data also demonstrate a higher prevalence of B-cell non-Hodgkin's lymphoma in HCV-infected patients with autoimmune manifestations 147148149 including Sjorgren syndrome 210, cryoglobulinemia 211212 and systemic lupus erythematosus (SLE) 213214. Adenovirus infection is associated with childhood leukemia, (151) and family studies in acute childhood leukemia have shown possible associations with autoimmune disease 215. Epstein-Barr virus 216 and human T lymphotropic virus type 1 infection 217 is associated with abnormal lymphoproliferation and Hodgkin's lymphoma. Cytomegalovirus infection is linked to autoimmunity 218 and testicular cancer 152.

H. pylori infection can lead to autoimmune neutropenia and MALT-lymphoma 154 in addition to its well-established role in the development of gastric cancer. Systemic rheumatic disease has also been linked to lymphoid malignancy 219. These findings underline a close relationship between infection, autoimmunity and proliferative disorders, possibly mediated by an abnormally functioning cytokine signaling network 220.

Antinuclear antibodies (ANA) were demonstrated in the sera of 19% of patients with malignancies in the absence of overt autoimmune manifestations 221. In cancer patients, a large number of autoantibodies are observed against tissue-specific antigens, nucleoproteins, membrane receptors, proliferation-associated antigens, tissue-restricted antigens, etc. [reviewed in 222]. Autoimmune connective tissue disorders are also commonly associated with malignancies 223. It was reported that gastric atrophy and pernicious anemia carries a risk for gastric carcinoma 18 times that of the population average 224. It appears that a variety of infections may induce autoimmune serological features without overt autoimmune disease or organ involvement 225; however, this condition may progress to clinical autoimmune disease and malignancy if impaired T cell function prevails. Such condition develops at a higher frequency among the elderly 226.

It was observed 30 years ago that a low percentage of human T cells (3.4%) have the ability to form auto-rosettes with autologous erythrocytes; in breast cancer and melanoma patients, the ratio was elevated to 6.1% and 7.4%, respectively 227. This observation implied that some level of autoreactivity is normal, confirmed later by studies on T cell tolerance 228229. However, the observation also pointed to an elevated level of autoreactive T cells involved in cancer. The mechanism of activation of an autoreactive T cell response was linked subsequently to bacterial and viral infections through the process of molecular mimicry 218230231232233234 in which pathogen-derived peptides mimic self-peptides. This phenomenon was studied in animal models 235236237238239240 and was supported by clinical observations 241242243. As a highlight, when lymphocytic choriomeningitis virus (LCV) antigens were expressed in the pancreas of transgenic mice, infection with the virus led to autoimmunity and diabetes 239.

H. pylori antigens mimic epitopes on H⁺, K⁺-adenosine triphosphatase in the gastric mucosa 230 thereby activating cross-reactive gastric T cells. Viral peptides mimic sequences on myelin basic protein 234, leading to multiple sclerosis. Cytochrome c (cyt c) as an antigen was used to study how self-proteins prime autoreactive T cell responses 244245, as SLE patients possess autoantibodies to cyt c 246. When non-self cyt c was co-administered with the self-protein, B cells specific for the foreign antigen primed autoreactive T cells that led to breaking tolerance to self-cyt c. The same autoimmune phenomenon occurs in the LCV transgenic mice when LCV antigens on pancreatic cells and the intact virus antigens are co-presented to the immune system 239. Therefore, it is quite likely that autoimmunity spontaneously develops during a variety of infections when antigens on microorganisms mimic self antigens and are presented together, breaking T cell tolerance.

The presence of autoreactive T cells has been observed in healthy persons, which indicates a role for these cells in immune defense. If autoreactive T cells were always absent from the T cell repertoire, the responsiveness toward foreign antigens that resemble self-antigens would be reduced. This notion is supported by the observation that T cells which recognized variants of self-antigen are of lower avidity than those recognizing a foreign antigen 247248. Also, tolerance to self-antigen reduced T cell variants for these peptides as well as the diversity of T cell receptor α and β-chain sequences of self-specific T cells 249250. It appears that some level of autoreactive T cells is necessary for immune defenses. Clinical autoimmunity may develop when persistent infection provides a continuing high dose of antigenic stimulus, 251 and this situation could predispose patients for the development of proliferative disorders.

Normal tissue development requires damaged, dangerous or unnecessary cells to be eliminated while healthy cells survive. The survival of harmful or damaged cells can lead to various pathologies. The evolutionarily conserved mechanism of apoptosis eliminates unwanted or abnormal cell populations. Lymphocytes require IL-2, IL-4, IL-7, IL-9 and IL-15 for viability 252253, and withdrawal of these cytokines leads to apoptotic cell death. Leukemia patients who went into complete remission following chemotherapy developed a different type of leukemia after being placed on IL-2 therapy 185. IL-2 is an essential cytokine for the viability of activated T-cells 254, suggesting a link between the survival of activated T-cells and leukemic cells. Myeloid leukemia cells are also cytokine-dependent and undergo apoptotic cell death following cytokine withdrawal 253. The various immune response-polarizing cytokines that tumor cells secrete 185186187188189190191192193194195196197198199200201 inhibit chemotherapy- or radiation-induced apoptosis 256257258259260261. There are myeloid leukemia cell lines that have become independent of an external cytokine supply 257, but generally cytokines can protect both normal and cancer cells against apoptosis induced by various cytotoxic agents. The persistence of infectious agents and chronic inflammation in cancer patients promotes NF-κB activation and inflammatory cytokine production, thereby contributing to the diminished apoptosis of abnormal cells 262263.

The completion of immune response against pathogenic microorganisms requires the deletion of activated T and B cells that participated in the immune defenses, particularly self-reactive ones 264 (although a fraction of them survive as memory cells). Apoptosis plays an important role in the regulation of peripheral immunity through the Fas/APO-1 cytotoxic pathway. Defective apoptosis can lead to autoimmune disease 265266 and cancer 267268. As cancer cells are not immortal, they maintain a program for apoptotic cell death 269.

The apoptosis marker Fas receptor (FasR) is expressed on numerous cell types, whereas the Fas ligand (FasL) is mainly expressed on T cells 266. FasL mediates the apoptosis of effector T cells as part of an immune response termination and tolerance development. FasL is also expressed in "immune-privileged" tissues such as the brain, testes and eyes with the purpose of preventing inflammation. Mutations in Fas or FasL can lead to autoimmune disease 270271. Similarly to cytotoxic T cells, various tumor cells also express FasL and use it to induce apoptosis of invading lymphocytes. Breast tumor cells express FasL that can kill Fas-sensitive lymphoid cells 272. The co-expression of Fas and FasL was observed in brain tumors that can use this mechanism to obtain a proliferating advantage by "counter-attacking" tumor-infiltrating activated Fas-sensitive T lymphocytes 273274. Similar observations have been made in Ewing sarcoma 275, gastric cancer 276, cholangiocarcinoma 277, B cell chronic lymphocytic leukemia (B-CLL) 278, colon adenocarcinoma 279280281, head and neck cancer 282, lung carcinoma 283, esophageal carcinoma 284, ovarian carcinoma 285, lymphoma 286, pancreatic carcinoma 287, melanoma 288, and other malignancies 289290. Childhood glial tumor cells (but not normal cells) in the brain express the common leukocyte-associated antigen and Fas 273.

The expression of apoptosis-related molecules on the surface of both neoplastic cells and cytotoxic lymphocytes (CTL) in tumor specimens raises the question of whether neoplastic cells are formed from CTLs by a premature termination of the apoptotic mechanism. Indeed, neoplastic cells behave like CTLs in their expression of FasL and in the induction of apoptotic death of activated T cells, as well as other cancer cells carrying a functional FasR 291292. In other words, cancer cells continue to act like T cells performing their immune-regulating functions.