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Hydrocarbons: Mechanisms of Cellular Toxicity

Hydrocarbons: Mechanisms of Cellular Toxicity. Organohalides Are Lipophilic. Less available for excr’n Accumulate in fatty tissues, fat stores Fatty tissue ½ life may be > 100 d Secr’d in milk Bioaccumulate in aquatic spp Partition out of water  Sediments  Fish fatty tissue.

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Hydrocarbons: Mechanisms of Cellular Toxicity

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  1. Hydrocarbons: Mechanisms of Cellular Toxicity

  2. Organohalides Are Lipophilic • Less available for excr’n • Accumulate in fatty tissues, fat stores • Fatty tissue ½ life may be > 100 d • Secr’d in milk • Bioaccumulate in aquatic spp • Partition out of water •  Sediments •  Fish fatty tissue

  3. www.ecoinfo.org/.../gbhtoxin/gbhtoxin_e.cfm • Organisms may accumulate 3-6x (or more) amt in env water

  4. Polynuclear Aromatic Hydrocarbons • Benzo(a)pyrene, benz(a)anthracene models • Metabolized by mixed function oxidases • Cytochromes P450 •  Reactive diol epoxides • Ox’d forms in bay region most toxic

  5. bay region

  6. Halogenated Hydrocarbons May Increase Their Own Toxicity • Work through Ah receptor • Induce prod’n Cyt P450 enz’s •  Oxidized cmpds • Ex: 7,8-Dihydro-7,8-dihydroxy-benzopyrene 9,10 epoxide

  7. The Ah–receptor binds four classes of substances: Dibenzodioxines (i.e TCDD) A, Dibenzofuranes, B Biphenyls C and polyaromatic hydrocarbons D. If such substances reach the receptor E, they trigger a chemical signal, which will finally result in toxic phenomena: tumor growth, skin toxicity (i.e. Ah mediated chloracne) F, immunotoxicity as well as developmental toxicity. The dioxin receptor belongs to the class of receptors mediating toxicity, which are preferentially modelled by QSAR methods. 3r-training.tierversuch.ch/.../dioxin.html

  8. Hydrocarbon binds Ah receptor in cytosol • Complex translocates  nucleus •  Specific recognition sites on DNA for complex • Ah gene locus • Now transcr’n, transl’n initiated • Specific genes code for AHH • Aryl hydrocarbon hydroxylase • Phase I enzyme • Structural gene for cytosolic receptor

  9. Increased Toxicity of Metabolites • Now more metabolic (Cyt P450) enz’s • Catalyze more ox’n of parent cmpd • Product now more toxic • Incr’d carcinogenesis • May covalently bind DNA •  Mutations, incr’d repl’n

  10. PolyChlorinated Biphenyls • “PCB’s” • 210 poss congeners • Chem cmpd closely related to another in composition • Exerting similar or antagonistic effects • Something derived from same source or stock • Widespread, persistent • In fat tissue of most humans

  11. Two most potent • 3,4,3’,4’-tetrachloro biphenyl • 3,4,5,3’,4’,5’-hexachloro biphenyl

  12. Halogen Substitutions • Cl is a halogen • F, Cl, Br, I • Reactive • Wants 1 e- to fill outer shell • Form ions w/ single negative charge

  13. In halogenated hydrocarbons, Cl covalently bound to C • Electronically stable bond • Most mol’s containing Cl man-made •  incr’d molecular stability, incr’d MW, incr’d bpt/mpt

  14. Cl substitutions on biphenyl often balanced • When ortho substituted w/ Cl • Cl relatively large • 2 planar rings can’t rotate • Rotation hindered by Cl’s • When no Cl, 2 planar rings can rotate • About C1, C1’ bond

  15. PCB Toxicity • Low acute toxicity • Chronic exposure not understood • Probably more harmful • Combines w/ receptor • Ah (aryl hydrocarbon) receptor • PCB  PCB-Receptor  Nucleus  DNA  alter transcription  effect on cell

  16. Three Modes of Action • Bind cell macromol’s • DNA • “Stacks and sticks” to proteins • Accumulate in lipid-rich cell components • Reversibly bind receptors, enzymes • At specific sites • Ah receptor has great affinity for TCDD, PCB’s • Via Cl’s

  17. PCB Biotransformation • Bioactivation depends on planarity • More toxic (and more similar to dioxin) when • Coplanarity of rings • Cl’s at m, p positions • Metab’d through Phase I and Phase II

  18. Phase I Metab • Cytochrome P450 monooxygenase common • Indirect hydroxylation • OH added, then db in ring shifts • Epoxidation • --O– added over db in ring • May or may not shift or lose Cl • Metab rate depends on #, placement Cl’s • More rapid if >4 Cl’s and H’s on C’s 4,5

  19. Phase II Metab • Phase II Reactions • Conjugated to glucuronic acid • Rapidly excr’d • Conjugated to GSH •  Mercapturic acid • Excr’d or reabs’d

  20. Common Effects of PCB’s • Note: many effects are species-specific • Coplanarity of rings, #Cl’s related to potency • Chloracne • Acneiform eruption w/ exposure • Milder than w/ TCDD • Probably diff mech

  21. Epithelial cell changes • Hyperplasia – Incr’d cell # w/ incr’d cell div’n • Hypoplasia – Decr’d cell division  decr’d # proliferating cells • Impt to changes in sev organs • Hepatomegaly • Gastric mucosal changes •  Ulceration, hemorrhage • Species specific • May play role in carcinogenesis • Hyperplasia = incr’d cell division; may be precursor for … • Cancer = unrestrained cell division

  22. Vit A depletion • May be linked to Ah receptor • Heme prod’n inhib’d • Get build-up of porphyrins which are toxic • Immunosuppression • Lymph glands • Spleen enlargement • Thymus gland atrophy • Total serum Ig’s decline (species specific) • Humans: IgA, IgM sig depressed • Phagocyte #, T cell response depressed • From Japan, Taiwan PCB poisoning epidemics

  23. Nervous system disorders • Catecholamine levels changed • Behavioral, learning dysfunctions • Offspring following prenatal exposure • Endocrine disruption • Next week’s lecture

  24. Dioxins • Also widespread • Also hydrophobic • Most toxic • 2,3,7,8-tetrachlorodibenzo-p-dioxin

  25. “Supertoxic” cmpd • Extremely potent • Diff isomers differ in toxicity • Contaminant of other chlorinated cmpds • Induces microsomal enz’s • May be through Ah receptor

  26. TCDD binds Ah receptor in cytosol • Some spp (even diff strains) have varied amts Ah receptor in cytosol • More receptor/higher sensitivity to TCDD • Complex translocates  nucleus •  Specific recognition sites on DNA for complex • Ah gene locus

  27. Now transcr’n, transl’n initiated • Specific genes code for AHH • Aryl hydrocarbon hydroxylase • Phase I enzyme • Structural gene for cytosolic (Ah) receptor • Other prot’s impt for immune, inflamm responses (?) • Other prot’s impt to cell viability, replication

  28. http://www.med.ufl.edu/pharm/facdata/Shiveric/images/TCDD.gifhttp://www.med.ufl.edu/pharm/facdata/Shiveric/images/TCDD.gif

  29. Toxicity in Humans Uncertain • Incr’d cancer mortality? • Carcinogenic in rats (@ 2 ppb) •  Cancers of liver, resp tract, mouth, others • “Not reported to be carcinogenic in humans in spite of its extremely potent carcinogenicity in rats” (WHO, 1989) • German pesticide workers suffer 39% higher cancer mortality rate compared to other Germans. (Hanson, David; 1991)

  30. Chloracne • Most characteristic lesion in humans • Related to Ah receptor • Hepatotoxicity at high doses • See hyperplasia, enzyme induction, others • Immunosuppression • T cells most likely target • Species specific • Reversible • Teratogenicity/fetotoxicity • Cleft palate/Ah receptor linked in mice? • Prenatal exposure  biochem & behavioral changes in offspring

  31. Some Problems in Assessing Toxicity • TCDD, congeners may be by-products of manufacture along with PCB’s • So which is responsible for toxicity? • DDT often present in mixtures, animals, environment • Pesticide, but also manufacturing by-product • OR may be in environment previously • OR may have been in animal fat from earlier exposure

  32. One toxicant may influence others in mixture • Synergism or antagonism • Which in a mixture is most toxic? • Can’t fully assess mechanisms • Difficult to assess environmental risk • Molecule in largest concent may not be most toxic • If one toxicant induces metab of another: ???? • Species specificity impt • Fat stores? (ex: mink)

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