IODINE INTAKE AND CANCER

Objectives: Iodine is a trace element that is essential for the synthesis of thyroid hormone. Both chronic iodine deficiency or iodine excess have been associated with hypertrophy and hyperplasia of follicular cells in thyroid gland and the influence of thyroid hormone （ T 3 , T 4 ） and thyrotropin （ TSH ） secretion. Increase rates of the thyroid cancer are increasing after radiation exposure to 131 I in children or aldolescents. Methodology: In respective published reports in literature and in combination of our previous study, dietary iodine excess goiter, iodine induced hyperthyroidism (IIH) and IIT, Iodine intake and the prevalence of papillary carcinoma （ PTC ） ,as well as the case-control and cohort studies of thyroid cancer and intake of seafood and milk products, were systematically reviewed. Relative factors that should be considered when studying the effect of dietary iodine in the development of thyroid cancer include screening programs, pathological criteria, diagnostic techniques, radioactive iodine, and standard of medical care in the studied population. Results and conclusion: In current surveys, papillary thyroid carcinoma forms the largest group of thyroid malignancies, after iodine intake excess or iodine prophylaxis where an increase in the papillary: follicular carcinoma ratio was uncovered. Also,there is clear temporal relationship in many countries between introduction of iodine intake excess especially as to radioactive iodine and an increase in incidence of PTC. Iodine goiter, IIH and IIT were also noted. Autoimmune hashimoto's thyroiditis are linked to dietary iodine. Dietary iodine intake is another care of environmental relevance factor in thyroid diseases and papillary carcinoma. Available evidence of oncogenic thyroid hormone receptor mutants from animal experiments and clinical investigation have been a shift toward the oncogenic function of human thyroid carcinoma, and also its target therapy.


INTRODUCTION
The main function of the thyroid gland is to make hormones 1 ,T 4 and T 3 are key regulation of metabolic effects such as the development of the brain in neonatals, the rapid development of frogs from thyrectomized tadpoles, the induction of growth hormone in the pituitary, and others lipogenesis, ketogenesis, and cellular proliferation and differentiation. Iodine is a trace essential raw element where 65% of T 4 weight is iodine. We have previously illustrated the biochemical synthesis of throxine 2 . Iodine supply, either too much or too little, impairs adequate synthesis of thyroid hormone. In experimental animals, in rats development of thyroid neoplasm following radioactive iodine was well established in earlier 1950-1964 last century. Since 1950, an extensive study of benign and malignant thyroid tumors induced, in the rats and mice, with radioiodine 3, 4 . In this paper, we are in further deliberating the topic entity of iodine excess induced thyroid diseases and papillary carcinoma (PTC). Exposure to radioactive iodine in induction of thyroid neoplasm in rat Since 1941, due to its lack of significant adverse effects and low cost, radioiodine-131 ( 131 I) has been successfully administered therapy or diagnosis of patients with benign thyroid disease. Up to recent, there was the investigation of the relationship between cancer risk following the therapeutic use of 131 I in benign thyroid disease provide conflicting results regarding several long-term cohort studies in Sweden 5 , England 6 , Finland 7 , Japan 8 and the US 9 . There was no increase in burden of cancer risk overall after 131 I administration. However, there was a tendency toward increase in thyroid cancer risk for women <40 years old following diagnostic 131 I. Moreover, a significant risk of thyroid cancer has been observed after administration of therapeutic X-radiation with doses as high as 60 Gy in childhood 9 . In animal models, it has been found that animals on an iodine-restricted diet were more likely to develop cancer 10, 11 . C3H/Hey strain-mice were placed in lowiodine diet can induce benign and malignant thyroid tumors 10 . Male Sprague-Dawley rats in chronic iodinedeficiency, long-term of approximately 10% of normal iodine dietary escalated to 60 times the normal concentration developed follicular hypertrophy and subsequent hyperplasia of follicular cells, and a massive increased proliferation rate 11 . This represents an in vivo model of low iodine dietary supply in tumorigenesis in the rats 12-18 . Moreover, in rats with containing carcinogens N-nitrosobis (2-hydroxypropyl) amine (BHP) and an excessive iodine diet 15, 16 , the incidence of thyroid cancer was 29% in those fed the excessive iodine diet versus 33% in those fed the iodine sufficient diet. In saline-treated rats, iodine deficiency or excess alone was not carcinogenic, but in BHPN-treated rats, both iodine deficiency and excess increased thyroid follicular tumors. The incidence of rats with benign nodules was 100% in both group. Boltze 17 fed rats over a period of 110 weeks high (~10 fold of normal), normal, and low (~0.1 fold of normal) daily iodine intake and subjected them to single external radiation of 4 gray (Gy) or sham radiation. Alone, both iodine deficiency and excess increased the thyrocyte proliferation rate and induced thyroid adenomas, but induced no thyroid carcinomas. Combined with radiation, both iodine deficiency and iodine excess induced thyroid carcinomas (PTC and follicular thyroid carcinomas, FTC) in 50-80% of animals, while iodine sufficient animals did not develop thyroid carcinomas. These findings suggest that both long-term iodine deficiency and excess may be a weak promoter of thyroid cancer albeit its insufficient to stimulate thyroid carcinogenesis. The overall incidence of thyroid carcinoma is generally considered without influence from the iodine intake in a given population. Iodine deficiency caused a high incidence of follicular tumor, while iodine intake dietary supply shifts the distribution towards papillary tumors 18 . In a Swedish study, papillary thyroid cancer was common in iodine-rich area. In a recent study on the effect of iodine intake on thyroid diseases in China, 10 patients with thyroid cancer were identified in the area of excessive iodine intake. Moreover, another 13 new cases of thyroid cancer were diagnosed in this iodine excessive area 19 . Chronically high iodine intake have been associated with the development of goiter (i.e. hypertrophy and hyperplasia of the thyroid cells), and in turn, goiter linked to thyroid cancer risk, particularly in women. A number of epidemiological studies have attempted to illustrate the association between excessive iodine intake and the risk of developing thyroid cancer, with the majority (80%) of papillary thyroid cancers (PTC). Epidemiology of thyroid cancer induced by Chernobyl ionizing radiation exposure and risk of thyroid cancer in man An increased risk of thyroid cancer has been demonstrated in survivors of the atom bomb explosions in Japan in 1945 20 . On 26 April 1986, the most serious environmental disaster at the Chernobyl nuclear power station in northern Ukraine led to a dramatic increase in the frequency of childhood thyroid cancer in contaminated areas of Belarus, Ukraine, and Western Russia 21-28 . The report of the United Scientific Committee on the Effects of Atomic Radiation (UNSCEAR) 21 provide estimate of the thyroid cancer risk in children from exposure to radioiodine. More than 10 million people were exposed to significant levels of radiation. The Chernobyl accident released huge amounts of radioactive materials into atmosphere, including 1.8x1018Bq of 131 I, 2.5x1018 of 133 I, and 1.1x1018 Bq of 132 Te,which decays to 132 I (UNSCEAR, 2000) 21, 22 . It has been estimated that more than 80% of thyroid dose came from internal exposure to 131 I, and the dose was 3-10 times higher in children than in adults. Beginning in 1990s,a dramatic increase in the incidence of pediatric thyroid cancer was noted in Belarus, and one or two years later in northern Ukraine and Western areas of Russia. In Belarus, children under the age of one year at the time of exposure had a relative risk of 237,whereas those aged 10 showed a relative risk of 6 22,23 . Those radiation associated thyroid cancers showed a higher the excess relative risk (ERR) of thyroid cancer involving younger age at the time of exposure 22,24 . Moreover, there are also reports of a twoto fourfold increase in thyroid carcinoma in adults from exposed areas 22,23 . When comparison of typically 5-10 years prior to Chernobyl, in a series of 472 patients from Belarus 22,25 , the average latency between exposure and cancer diagnosis was 6.9 years. The vast majority of post-Chernobyl pediatric thyroid cancers were papilliary carcinoma. Histopathological features appears as sheets of malignant epithelial cells surrounded by varying amounts of fibrotic stroma. Post-Chernobyl thyroid cancers were clinically high prevalence of solid growth pattern, and more aggressive at presentation. In molecular analysis (Table  1), RET/PTC rearrangement has been found in 66-87% of all post-Chernobyl tumors. RET/PTC is formed by an intrachromosomal inversion of the long arm of chromosome 10 resulting in the fusion of RET with the H4/D10S170 gene, which implicate RET/PTC as a key first step in papillary thyroid cancer pathogenesis 26-28 .
In post-Chernobyl children with PTC, RET/PTC3 rearrangement was strongly associated with solid variant PTC with a short latent period after exposure, while RET/PTC rearrangement was mainly linked to conventional PTC with a long latent period after exposure 29, 30 . Another rearrangement was about 7% of radiation-induced papillary carcinomas involving the nerve growth factor gene NTRK1 31 . Recently, a new paracentric inversion of chromosome 7q leads to an inframe fusion between exons 1-8 of the AKAP9 gene and exons 9-18 of BRAF. The fusion protein transforms NIH3T3 cells, confirming its oncogenic properties 32, 33 .

Iodine induced goiter, hyperthyroidism(IIT)and thyrotoxicosis(IIT)
According to WHO in 1994 34 and the Korea Centers for disease control and prevention (KCDC) in 2012 35 food products such as processed, agricultural, meats, and marine products were monitored for measuring dietary iodine. The recommended iodine daily allowance of 70-150µg 36  IIT. The incidence of IIH in an endemic goiter has been up to 1.7% (Martin, 1989). At the population of the metropolitan area of Greater Buenos Aires (11 million inhabitants), an iodine sufficient area, Niepominszoze 48 examined the epidemiology of palpable goiter. In the Random Group, goiter prevalence was 8.7% while in the Induced Group, which concluded among relatives of patients with thyroid disorders and other complaints, it climbed to 14.4%. Both groups were mostly made up of women (87.2%).The epidemic data presented the first arising from a screening survey carried out in a large iodine-sufficient population of the Southernmost of the American Continent.
To further study the effect of excess iodine and excess tyrosine on goiter in mice 49 , high iodine feed (high iodine and adequate tyrosine, HIAT) could result in the typical colloid goiter in mice and the goiter rate was 89.5% whereas 35% of goiter was observed in both iodine and tyrosine excess (HIHT), and no goitet was noted in only high tyrosine (AIHT). The results implicate that both iodine and tyrosine played a key role in goiter, and iodine excess having a markedly stronger effect, and goiter was characterized by large follicles with flat epithelium and abundant colloid mixed with normal or larger-sized follicles lined by epithelium of increased thyroid weight. Moreover, there existed positive association between goiter rate of mice and iodine doses 50 . The differential goiter rate of 10%, 50% and 90% could be induced by drinking water at different iodine doses 250, 1500 and 3000µg/L respectively. The dose of iodine 250µg/l was able to induce colloid goiter in mice.  53 Iodine-induced hyperthyroidism (IIH) has been frequently described when iodine is introduced into an iodine-deficient area, patients residing in iodinesufficient areas 54 and iodinated preparation for water purification 55 or a long-term topical iodine application or by intravenous administration of iodine-containing substances 56-58 . In a classical study, four euthyroid patients with a single autonomous nodule from the slightly iodine-deficient Brussels region received a supplement of 500ug iodine per day. This caused a slow but constant increase of thyroid hormone. After four weeks, the patients became hyperthyroid 59 . Therefore, IIH is frequently observed in patients affected by euthyroid iodine deficient goiter when suddenly exposed to excess iodine. The possibly the presence of autonomous thyroid function permits the synthesis and release of excess quantities of thyroid hormones. In rats serum thyroxine (TT 4 , FT 4 , rT 3 ) was higher in higher iodine than the result in lower iodine. Individuals with multinodular goiters living in iodinereplete regions can also develop hyperthyroidism, confirming that nodular goiters are particularly prone to developing IIT 43 . In iodine-sufficient areas, IIH has been reported in euthyroid patients with previous diseases. For instance, euthyroid patients previously treated with antithyroid drugs for Grave's diseases are prone to develop IIH. In East-Jutland Denmark and Iceland, it has been found that in the elderly population high incidence of multinodular toxic goitre in a low iodine intake area whereas high incidence of Grave's disease in young in a high iodine intake area 60 . Other IIH has been occasionally observed in euthyroid patients with a previous episode of post-partum thyroiditis, type II thyrotoxicosis, and in people with iatrogenic episodes of thyroid dysfunction (e.g. nonionic contrast radiography). In northern Tasmania in UK, in 1964 and in 1971 respectively, the incidence of thyrotoxicosis rose substantially because of the addition of iodate to bread to prevent goitre or iodine residues in milk 61 . In Vigo, Spain, dietary of iodine supplementation in iodine sufficient areas may induce the increase of thyrotoxicosis (TT) (7.68/100,000), as opposed to 3.1/100,000 in area without iodinized salt 62 . IIT has been reported after initiating iodine supplementation, also with use of iodinated drugs, radiographic contrast agents and food dietary iodine 5462 . Table 2 represent iodine-containing compounds related to IIH and IIT 54 . of iodine from marine products may increase thyroid cancer risk, particularly in women 76 .

Iodine intake and the prevalence of papillary carcinoma (PTC)
Dietary iodine intake act as a potential relavance risk factor of thyroid cancer 77-78 . Thyroid neoplasia can arise from many different causes. These include low iodine diets, radioactive iodine and natural goitrogens. Elevated incidence and mortality rate of thyroid cancer have been found in areas where iodine intake is high (Howaii, Iceland) 79, 80 . In South India, among 300 patients with goiter and 100 euthyroid non-goitrous volunteers, iodine-induced hyperthyroidism or IIT (34%) and thyroid cancer (15%) have been observed after continued supplement of edible salt fortified with excess iodine 81 . The prevance of PTC(80-90%) in thyroid carcinoma increased significant after USI. According to Zimmerann in recent review 12 and Williams the earlier review 82 , there were reports that in countries with 'high' iodine intake (US, Iceland)the ratio of PTC: FTC ranged from 3.4 to 6.5, while in countries with 'moderate' iodine intake (the UK and northern Germany) the ratio was from 1.6 to 3.7, and in countries with 'low' iodide intake (Argentina, Colombia, Finland, Southern Germany, Austria and Switzerland) the ratio was from 0. 19  Italy had one of the highest incidence rates for thyroid cancer, nearly 20/100,000 women in 2007, the frequency of thyroid cancer in females with cold nodules was 5.3% in the iodine sufficient area(mean UIC 114µg/l) and 2.7% in the iodine deficient area (mean UIC<50µg/l) 88 . Japan had also its highest incidence rates for thyroid cancer, where iodine intake is high 82 . Occult thyroid cancer (OTC) was more common in glands with nodular goiter (range 15.7%~28.4%) in areas of excessive iodine intake 89 . Therefore, in the presence of sufficient iodine intake, more than 80% of thyroid cancer consisted of papillary carcinoma (PTC), whereas in area with iodinedeficiency, in contrast, have a higher incidence of FTC 90 . Compared with matched controls, urinary excretion of iodine excess was detected in 302 cases of thyroid benign tumors (519µg/L) and 240 thyroid cancers (524µg/L) (Liu, 2008 THRA1 allele that was co-amplified with ERBB2 in breast cancer. Moreover, in clinics, there were 63% of 16 papillary thyroid carcinoma (PTC) expressing mutations in THRa1, and a 94% in THRbeta1, in contrast to 22% and 11% of thyriod adenomas harboring mutations in these isoforms respectively, and no mutations were found in normal thyroid controls. The results indicated the differential effects of normal and oncogenic thyroid hormone receptor 111 signaling in PTC and normal controls. The findings suggest a possible oncogenic action of thyroid hormone receptor mutation in the tumorigenesis of human thyroid carcinoma 110 . Others, anaplastic thyroid cancers harbor novel oncogenic mutations of ALK gene 112 . Oncogenic receptor ALK belongs to an insulin receptor (IR) or oncogenic receptor IGF-1R family 113 . TLR4 stimulation with its ligand lipopolysaccharides promotes KSHV-induced cellular transformation and tumorigenesis via activating the STAT3 pathway 114 . TLR4 mediated tumorigenesis while TLR4 antagonist CL1095 inhibit it. Toll-like receptor (TLR4) induced pro-oncogenic or also protumoral function in head and neck carcinoma 115 . More others, CLIC1 was identified as a novel dominant pro-oncogenic receptor from proteomic profiling of pleomorphic human sarcoma 116 . Thus, an extensive study of thyroid hormone receptor (THR) mutations in oncogenic signaling, TSH/TSHR in thyroid disease and thyroid cancer, and also its target therapy 117-119 , is further perspective.