ࡱ> `RdO)NSPowerPoint Document(RSummaryInformation(TLDocumentSummaryInformation8|R  !"#$%&'()*+,-./0123456789:;<=>?@ABCDEFGHIJKLMNOPQ_UVWXYZ[\]^a8(x T/0(  0;[0 0 000$([\{b00 000000000  0=] 0 0 0000 2 3 !A0C0E0G0I0c00000000000000000!%),.:;?]}acdeghijklmnop|DTimesingbatsPss&DHelvetica BlackPss& DHelveticaBlackPss&0DZapf DingbatskPss&@DArialingbatskPss&g.Z@  @@``  @n?" dd@  @@`` 8FC("?8(*Na-R)      01? inC_@y g4idids{t|m p|p< <4dddd``gʚ;uʚ;2Nʚ;<4!d!d``uʚ;<4dddd``uʚ;~___PPT9`X(.)/-0*1,23"4 h___PPT2001D<4X? %,EEssentials of Glycobiology Lecture 43 June 10, 2004 Ajit Varki DF$( : Course Overview & Summary 9(r Universal Principles of Glycobiology: Glycan Occurrence::,  All cells in nature are covered with a dense and complex array of carbohydrate chains(glycans) Most secreted proteins of eukaryotes also carry large amounts of covalently attached glycans. In eukaryotes, these cell surface and secreted glycans are assembled via the ER-Golgi pathway$pmU< $PVW0 A.r Universal Principles of Glycobiology: Glycan Occurrence::,  6The extracellular matrix of eukaryotes is also very rich in glycans that are secreted via the same pathway Cytosolic and nuclear glycans are also common in eukaryotes For topological, evolutionary and biophysical reasons, there is little similarity between cell surface/secreted and nuclear/cytosolic glycans.$7pmU< 7$b) &  ;)x Universal Principles of Glycobiology : Glycan Biosynthesis==,  OThe primary units of glycans (monosaccharides) can be synthesized within a cell or salvaged from the environment Monosaccharides must be activated into sugar nucleotides before they are used as donors for glycosyltransferases. Topological barriers are relevant. Each linkage unit is assembled by one or more unique glycosyltransferases8PpmU< ; $ Z CLZB/x Universal Principles of Glycobiology : Glycan Biosynthesis==,   Many glycosyltransferases are members of multigene families with related functions Most glycosyltransferases recognize the underlying glycan substrate, but some are protein-specific Many glycosyltransferases are expressed in a tissue-specific, temporally regulated manner $pmU<  b $-A?-p Universal Principles of Glycobiology: Glycan Diversity99,  Monosaccharides have the potential for far greater combinatorial diversity than nucleotides or amino acids Further diversity can arise from covalent modifications of glycans Only a limited subset of the potential diversity is found in a given organism or cell type. However, there is intrinsic diversity (microheterogeniety) within a given cell type or even a single glycosylation site $pmU< H,C0p Universal Principles of Glycobiology: Glycan Diversity99,  The glycan repertoire (glycome) of a given cell-type or organism is thus many orders of magnitude more complex than the genome or the proteome The glycan repertoire (glycome) of a given cell-type or organism is also highly dynamic, responding to intrinsic and extrinsic signals by under going rapid changes Glycome diversity in species, space and time can help explain why there are only a limited number of genes in the typical genome$pmU< b t y<*t Universal Principles of Glycobiology: Glycan Recognition;;,  yGlycans can be recognized by many specific-binding proteins intrinsic to the organism synthesizing the glycans Glycans are also recognized by many binding proteins of pathogens and symbionts Glycan-recognizing proteins often show a high degree of stereospecificity for binding to specific glycan structures, but typically have relatively low affinities for single site binding$zpmU< zZ_?2QD1t Universal Principles of Glycobiology: Glycan Recognition;;,  H Thus, biologically relevant recognition usually requires multivalency of glycan and receptor, in order to generate high avidity of binding Glycan-recognizing proteins fall into two categories: those with common evolutionary origins (e.g., lectins) and those that have evolved by convergent evolution (e.g, GAG binding proteins)>pmU< HpmU< I P9:]R=,p Universal Principles of Glycobiology : Glycan Genetics99,  ]Naturally occurring genetic defects in cell surface/secreted glycans seem relatively rare in intact organisms. However, this may be due to an ascertainment bias caused by unpredictable or pleiotropic phenotypes Genetic defects in cell surface/secreted glycans are easily obtained in cultured cells, but have somewhat limited biological consequences$^pmU< ^ >=w 3 YE2p Universal Principles of Glycobiology : Glycan Genetics99,  1 The same mutations typically have major phenotypic consequences in an intact multicellular organism This implies that many of the major roles of cell surface/secreted glycans involve cell-cell or extracellular interactions Nuclear/cytosolic glycans may play more cell-intrinsic roles e.g., in signalling.>pmU< 1pmU< 2 bMK + * tBiological roles for glycans span the spectrum from non-essential activities to those that are crucial for the development, function and survival of an organism All of the theories regarding the biological roles of glycans appear to be correct, but exceptions to each can be found Glycans can play different roles in different tissues, or at different times in development&uxmU< u ,9 TF3 n Terminal sequences, unusual glycans, and modifications are more likely to mediate specific biological roles However, unusual glycans or modifications might also reflect prior evolutionary interactions with microorganisms and other noxious agents Thus, a priori prediction of the functions of a specific glycan or its relative importance to the organism is difficultXxmU< nxmU2   j >Y 82"d Universal Principles of Glycobiology : Evolution33   Relatively little is known about the glycan evolution Inter-species and intra-species variations in glycan structure are relatively common, suggesting rapid evolution Most likely mechanism for rapid evolution is selection pressure by pathogens than recognize glycans$ pmU<  6%8G4d Universal Principles of Glycobiology : Evolution33  l However, glycan evolution must also preserve critical intrinsic functions Interplay between pathogen selection pressure and preservation of intrinsic roles could also result in the formation of  junk glycans Such  junk glycans could be the substrate from which new intrinsic functions arise during evolution$7pmU< 7 >   Q0 Future Perspectives Improvements in analytical methods will speed analysis of glycan mixtures Improvements in synthetic methods will make available custom glycans in large quantities for therapeutics and as analytical reagents Model organisms will continue to grow in utility as genomic initiatives expand and better genetic tools come on-line Nutritional and environmental factors will be important in modulating glycan structure and functions $pmU< >:F  PPsxHHR[g$vVHH( 'h ` ` ̙33` ` ff3333f` 333MMM` f` f` 3>?" dZ@z? " dZ@  @" `  n?" dZ(@   @@``PR    @ ` ` p>  >   .(    Z`h+ 8c 8c1 ?L  T Click to edit Master title style! !<  c $m\ ? `'P(C &Microsoft Office 98L  0( fa j  s *1 ?_  B  s *޽h ?  @ 0(   B  s *޽h ?  4, (    # l| 8c 8c1 ?m     Z |wawa1 ?    "H  0m\ ? `'P(C  0(P( <    6/.x     N`/.? 1?#" `xI<$< 0  %cH  0m\ ? `'P(C  D<`( X?   S @1. 8c 8c     ? A@ A1 8c8c     ?1 d0u0@Ty2 NP'p<'pA)BCD|E||c"$`x     N1.? 1?#" `6x<$< 0  %cH  0m\ ? `'P(C  D<p(    S @4. 8c 8c     ? A@ A1 8c8c     ?1 d0u0@Ty2 NP'p<'pA)BCD|E||c"$`x     N4.? 1?#" `P <$< 0  %cH  0m\ ? `'P(C  D<(    S ~ 8c 8c     ? A@ A1 8c8c     ?1 d0u0@Ty2 NP'p<'pA)BCD|E||c"$`x     N~? 1?#" `xg<$< 0  %cH  0m\ ? `'P(C  D<( (   S ~ 8c 8c     ? A@ A1 8c8c     ?1 d0u0@Ty2 NP'p<'pA)BCD|E||c"$`x     N0].? 1?#" `x <$< 0  %cH  0m\ ? `'P(C  D<( <   S P^. 8c 8c     ? A@ A1 8c8c     ?1 d0u0@Ty2 NP'p<'pA)BCD|E||c"$`x     N^.? 1?#" `x$ <$< 0  %cH  0m\ ? `'P(C  D<(    S _. 8c 8c     ? A@ A1 8c8c     ?1 d0u0@Ty2 NP'p<'pA)BCD|E||c"$`x     Np_.? 1?#" `x <$< 0  %cH  0m\ ? `'P(C  D<( 4P   S `. 8c 8c     ? A@ A1 8c8c     ?1 d0u0@Ty2 NP'p<'pA)BCD|E||c"$`x     N`.? 1?#" `x <$< 0  %cH  0m\ ? `'P(C  D<( 1   S Pa. 8c 8c     ? A@ A1 8c8c     ?1 d0u0@Ty2 NP'p<'pA)BCD|E||c"$`x     Na.? 1?#" `xB <$< 0  %cH  0m\ ? `'P(C  D< (      S b. 8c 8c     ? A@ A1 8c8c     ?1 d0u0@Ty2 NP'p<'pA)BCD|E||c"$`x      N0c.? 1?#" `Px[ <$< 0  %cH   0m\ ? `'P(C :2(    NPd.? 1?#" `x <$< 0 ,f  V   3 rd. 8c 8c?1?#" `x j Universal Principles of Glycobiology : Glycan Roles66, H  0m\ ? `'P(C :2( 8   Nh.? 1?#" `x <$< 0 ,f  V   3 rL 8c 8c?1?#" `x j Universal Principles of Glycobiology : Glycan Roles66, H  0m\ ? `'P(C  :2( x   BL1 ?@xo <$< 0  ?   60L 8c 8c     ? A@ A1 8c8c     ?1 d0u0@Ty2 NP'p<'pA)BCD|E||c"$`x   H  0m\ ? `'P(C  :2 ( |F   BL1 ?x <$< 0  ?   6PL 8c 8c     ? @ 1 8c8c     ?1 d0u0@Ty2 NP'p<'pA)BCD|E||c"$`x   H  0m\ ? `'P(C  :20(    3 L 8c 8c     ? 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