KnotProt 2.0: A database of proteins with knots and slipknots

Found 237 chains in Knotoided chains table. Displaying 1 - 150. Applied filters: Probabilistic

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Knots
Knotoids

Search results query: topological notation for knotoids: S 3.1, 2.1

#pdbid|chain|deposition date|is S/K-not|(slip)knot types;
      
  6mp6|A|2019-11-15|S|3.1 2.1;
  6scf|A|2019-11-07|S|3.1 2.1;
  6prm|A|2019-10-19|S|3.1 2.1;
  5kgn|A|2018-10-20|S|3.1 2.1;
  5vpu|A|2018-10-19|S|3.1 2.1;
  3e2d|A|2018-10-19|S|3.1 2.1;
  3q3q|A|2018-10-19|S|3.1 2.1;
  5xwk|A|2018-09-26|S|3.1 2.1;
  5kgl|A|2018-09-26|S|3.1 2.1;
  5xnu|A|2018-09-14|S|3.1 2.1;
  5tj3|A|2018-09-13|S|3.1 2.1;
  5znm|A|2018-09-13|S|3.1 2.1;
  5g2v|A|2018-09-12|S|3.1 2.1;
  5ijs|A|2018-06-28|S|3.1 2.1;
  3nkm|A|2018-06-27|S|3.1 2.1;
  3nkp|A|2018-06-27|S|3.1 2.1;
  3wav|A|2018-06-27|S|3.1 2.1;
  3wax|A|2018-06-27|S|3.1 2.1;
  4b56|A|2018-06-26|S|3.1 2.1;
  3bdh|A|2018-06-26|S|3.1 2.1;
  4zg7|A|2018-06-12|S|3.1 2.1;
  5k4p|A|2018-06-12|S|3.1 2.1;
  5lrm|A|2018-06-12|S|3.1 2.1;
  5m0s|A|2018-06-12|S|3.1 2.1;
  5nj5|A|2018-06-12|S|3.1 2.1;
  5nja|A|2018-06-12|S|3.1 2.1;
  5tcd|A|2018-06-12|S|3.1 2.1;
  5udy|A|2018-06-12|S|3.1 2.1;
  5yle|A|2018-06-12|S|3.1 2.1;
  5ylf|A|2018-06-12|S|3.1 2.1;
  1ali|A|2018-06-12|S|3.1 2.1;
  1alj|A|2018-06-12|S|3.1 2.1;
  1alk|A|2018-06-12|S|3.1 2.1;
  1ani|A|2018-06-12|S|3.1 2.1;
  1anj|A|2018-06-12|S|3.1 2.1;
  1auk|A|2018-06-12|S|3.1 2.1;
  1b8j|A|2018-06-12|S|3.1 2.1;
  1e2h|A|2018-06-11|S|3.1 2.1;
  1e2i|A|2018-06-11|S|3.1 2.1;
  1e2j|A|2018-06-11|S|3.1 2.1;
  1e2k|A|2018-06-11|S|3.1 2.1;
  1e2l|A|2018-06-11|S|3.1 2.1;
  1e2m|A|2018-06-11|S|3.1 2.1;
  1e2n|A|2018-06-11|S|3.1 2.1;
  1e2p|A|2018-06-11|S|3.1 2.1;
  1e3c|P|2018-06-11|S|3.1 2.1;
  1ed8|A|2018-06-11|S|3.1 2.1;
  1ed9|A|2018-06-11|S|3.1 2.1;
  1elx|A|2018-06-11|S|3.1 2.1;
  1ely|A|2018-06-11|S|3.1 2.1;
  1elz|A|2018-06-11|S|3.1 2.1;
  1ew2|A|2018-06-11|S|3.1 2.1;
  1ew8|A|2018-06-11|S|3.1 2.1;
  1ew9|A|2018-06-11|S|3.1 2.1;
  1fsu|A|2018-06-11|S|3.1 2.1;
  1hdh|A|2018-06-11|S|3.1 2.1;
  1hjk|A|2018-06-11|S|3.1 2.1;
  1hqa|A|2018-06-11|S|3.1 2.1;
  1k7h|A|2018-06-11|S|3.1 2.1;
  1kh4|A|2018-06-11|S|3.1 2.1;
  1kh5|A|2018-06-11|S|3.1 2.1;
  1kh7|A|2018-06-11|S|3.1 2.1;
  1kh9|A|2018-06-11|S|3.1 2.1;
  1khj|A|2018-06-11|S|3.1 2.1;
  1khk|A|2018-06-11|S|3.1 2.1;
  1khl|A|2018-06-11|S|3.1 2.1;
  1khn|A|2018-06-11|S|3.1 2.1;
  1ki2|A|2018-06-11|S|3.1 2.1;
  1ki6|A|2018-06-11|S|3.1 2.1;
  1ki6|B|2018-06-11|S|3.1 2.1;
  1ki7|A|2018-06-11|S|3.1 2.1;
  1ki8|A|2018-06-11|S|3.1 2.1;
  1kim|A|2018-06-11|S|3.1 2.1;
  1n2k|A|2018-06-11|S|3.1 2.1;
  1n2m|A|2018-06-11|S|3.1 2.1;
  1o98|A|2018-06-11|S|3.1 2.1;
  1o99|A|2018-06-11|S|3.1 2.1;
  1ogc|A|2018-06-11|S|3.1 2.1;
  1ogd|A|2018-06-11|S|3.1 2.1;
  1oge|A|2018-06-11|S|3.1 2.1;
  1ogf|A|2018-06-11|S|3.1 2.1;
  1osn|A|2018-06-11|S|3.1 2.1;
  1p49|A|2018-06-11|S|3.1 2.1;
  1p6x|A|2018-06-11|S|3.1 2.1;
  1p72|A|2018-06-11|S|3.1 2.1;
  1p73|A|2018-06-11|S|3.1 2.1;
  1p75|A|2018-06-11|S|3.1 2.1;
  1p7c|A|2018-06-11|S|3.1 2.1;
  1qhi|A|2018-06-11|S|3.1 2.1;
  1rh1|A|2018-06-11|S|3.1 2.1;
  1shn|A|2018-06-11|S|3.1 2.1;
  1shq|A|2018-06-11|S|3.1 2.1;
  2anh|A|2018-06-11|S|3.1 2.1;
  2axc|A|2018-06-11|S|3.1 2.1;
  2b5u|A|2018-06-11|S|3.1 2.1;
  2g9y|A|2018-06-11|S|3.1 2.1;
  2ga3|A|2018-06-11|S|3.1 2.1;
  2glq|A|2018-06-11|S|3.1 2.1;
  2gsn|A|2018-06-11|S|3.1 2.1;
  2gso|A|2018-06-11|S|3.1 2.1;
  2hjn|A|2018-06-11|S|3.1 2.1;
  2iuc|A|2018-06-11|S|3.1 2.1;
  2iuc|B|2018-06-11|S|3.1 2.1;
  2ki5|A|2018-06-11|S|3.1 2.1;
  2nwl|A|2018-06-11|S|3.1 2.1;
  2nww|A|2018-06-11|S|3.1 2.1;
  2nwx|A|2018-06-11|S|3.1 2.1;
  2ob5|A|2018-06-11|S|3.1 2.1;
  2qzu|A|2018-06-11|S|3.1 2.1;
  2rh6|A|2018-06-11|S|3.1 2.1;
  2vtk|A|2018-06-11|S|3.1 2.1;
  2w5q|A|2018-06-11|S|3.1 2.1;
  2w5r|A|2018-06-11|S|3.1 2.1;
  2w5s|A|2018-06-11|S|3.1 2.1;
  2w5t|A|2018-06-11|S|3.1 2.1;
  2w5w|A|2018-06-11|S|3.1 2.1;
  2w5x|A|2018-06-11|S|3.1 2.1;
  2w8d|A|2018-06-11|S|3.1 2.1;
  2wcv|A|2018-06-11|S|3.1 2.1;
  2x98|A|2018-06-11|S|3.1 2.1;
  2xr9|A|2018-06-11|S|3.1 2.1;
  2xrg|A|2018-06-11|S|3.1 2.1;
  2zkt|A|2018-06-11|S|3.1 2.1;
  3bdf|A|2018-06-11|S|3.1 2.1;
  3bdg|A|2018-06-11|S|3.1 2.1;
  3bdg|B|2018-06-11|S|3.1 2.1;
  3cmr|A|2018-06-11|S|3.1 2.1;
  3dyc|A|2018-06-11|S|3.1 2.1;
  3e7n|A|2018-06-11|S|3.1 2.1;
  3ed4|A|2018-06-11|S|3.1 2.1;
  3f0t|A|2018-06-11|S|3.1 2.1;
  3igy|B|2018-06-11|S|3.1 2.1;
  3igz|B|2018-06-11|S|3.1 2.1;
  3kbc|A|2018-06-11|S|3.1 2.1;
  3lxq|A|2018-06-11|S|3.1 2.1;
  3m8y|A|2018-06-11|S|3.1 2.1;
  3m8z|A|2018-06-11|S|3.1 2.1;
  3mk0|A|2018-06-11|S|3.1 2.1;
  3mk1|A|2018-06-11|S|3.1 2.1;
  3mk2|A|2018-06-11|S|3.1 2.1;
  3mvk|A|2018-06-11|S|3.1 2.1;
  3nkq|A|2018-06-11|S|3.1 2.1;
  3nkr|A|2018-06-11|S|3.1 2.1;
  3nvl|A|2018-06-11|S|3.1 2.1;
  3ot9|A|2018-06-11|S|3.1 2.1;
  3p13|A|2018-06-11|S|3.1 2.1;
  3rdp|A|2018-06-11|S|3.1 2.1;
  3szy|A|2018-06-11|S|3.1 2.1;
  3szz|A|2018-06-11|S|3.1 2.1;
  3t00|A|2018-06-11|S|3.1 2.1;
  3t01|A|2018-06-11|S|3.1 2.1;
  3t02|A|2018-06-11|S|3.1 2.1;
  3tg0|A|2018-06-11|S|3.1 2.1;
  3tv9|A|2018-06-11|S|3.1 2.1;
  3twz|A|2018-06-11|S|3.1 2.1;
  3un2|A|2018-06-11|S|3.1 2.1;
  3un3|A|2018-06-11|S|3.1 2.1;
  3un5|A|2018-06-11|S|3.1 2.1;
  3uny|A|2018-06-11|S|3.1 2.1;
  3uo0|A|2018-06-11|S|3.1 2.1;
  3vtk|A|2018-06-11|S|3.1 2.1;
  4a34|A|2018-06-11|S|3.1 2.1;
  4cxk|A|2018-06-11|S|3.1 2.1;
  4cxs|A|2018-06-11|S|3.1 2.1;
  4cxu|A|2018-06-11|S|3.1 2.1;
  4cyr|A|2018-06-11|S|3.1 2.1;
  4cys|A|2018-06-11|S|3.1 2.1;
  4fdi|A|2018-06-11|S|3.1 2.1;
  4fdj|A|2018-06-11|S|3.1 2.1;
  4gtw|A|2018-06-11|S|3.1 2.1;
  4gtx|A|2018-06-11|S|3.1 2.1;
  4gty|A|2018-06-11|S|3.1 2.1;
  4gtz|A|2018-06-11|S|3.1 2.1;
  4ivq|A|2018-06-11|S|3.1 2.1;
  4ivr|A|2018-06-11|S|3.1 2.1;
  4jbx|A|2018-06-11|S|3.1 2.1;
  4jby|A|2018-06-11|S|3.1 2.1;
  4kav|A|2018-06-11|S|3.1 2.1;
  4kjg|A|2018-06-11|S|3.1 2.1;
  4km4|A|2018-06-11|S|3.1 2.1;
  4lr8|A|2018-06-11|S|3.1 2.1;
  4lr9|A|2018-06-11|S|3.1 2.1;
  4lrb|A|2018-06-11|S|3.1 2.1;
  4lrc|A|2018-06-11|S|3.1 2.1;
  4lrd|A|2018-06-11|S|3.1 2.1;
  4lre|A|2018-06-11|S|3.1 2.1;
  4lrf|A|2018-06-11|S|3.1 2.1;
  4miv|C|2018-06-11|S|3.1 2.1;
  4miv|D|2018-06-11|S|3.1 2.1;
  4miv|E|2018-06-11|S|3.1 2.1;
  4miv|F|2018-06-11|S|3.1 2.1;
  4miv|H|2018-06-11|S|3.1 2.1;
  4nwj|A|2018-06-11|S|3.1 2.1;
  4oql|A|2018-06-11|S|3.1 2.1;
  4oqn|A|2018-06-11|S|3.1 2.1;
  4oqx|A|2018-06-11|S|3.1 2.1;
  4tn0|A|2018-06-11|S|3.1 2.1;
  4uoo|A|2018-06-11|S|3.1 2.1;
  4uop|A|2018-06-11|S|3.1 2.1;
  4uor|A|2018-06-11|S|3.1 2.1;
  5aj9|A|2018-06-11|S|3.1 2.1;
  5c66|A|2018-06-11|S|3.1 2.1;
  5dlv|A|2018-06-11|S|3.1 2.1;
  5dlw|A|2018-06-11|S|3.1 2.1;
  5egh|A|2018-06-11|S|3.1 2.1;
  5gov|A|2018-06-11|S|3.1 2.1;
  5grr|A|2018-06-11|S|3.1 2.1;
  5gs6|A|2018-06-11|S|3.1 2.1;
  5mx9|A|2018-06-11|S|3.1 2.1;
  5nj9|A|2018-06-11|S|3.1 2.1;
  5too|A|2018-06-11|S|3.1 2.1;
  5tpq|A|2018-06-11|S|3.1 2.1;
  5veo|A|2018-06-11|S|3.1 2.1;
  5ylc|A|2018-06-11|S|3.1 2.1;
  5zjv|A|2018-06-11|S|3.1 2.1;
  6b1v|A|2018-06-11|S|3.1 2.1;
  6bat|A|2018-06-11|S|3.1 2.1;
  6bau|A|2018-06-11|S|3.1 2.1;
  6bmi|A|2018-06-11|S|3.1 2.1;
  1e33|P|2018-06-11|S|3.1 2.1;
  1ura|A|2018-06-11|S|3.1 2.1;
  1urb|A|2018-06-11|S|3.1 2.1;
  1vpb|A|2018-06-11|S|3.1 2.1;
  1vtk|A|2018-06-11|S|3.1 2.1;
  1y6v|A|2018-06-11|S|3.1 2.1;
  1y7a|A|2018-06-11|S|3.1 2.1;
  1zeb|A|2018-06-11|S|3.1 2.1;
  1zed|A|2018-06-11|S|3.1 2.1;
  1zef|A|2018-06-11|S|3.1 2.1;
  3nko|A|2018-06-11|S|3.1 2.1;
  3waw|A|2018-06-11|S|3.1 2.1;
  3way|A|2018-06-11|S|3.1 2.1;
  1aja|A|2018-06-10|S|3.1 2.1;
  1ajb|A|2018-06-10|S|3.1 2.1;
  1ajc|A|2018-06-10|S|3.1 2.1;
  1ajd|A|2018-06-10|S|3.1 2.1;
  5ijq|A|2018-06-08|S|3.1 2.1;

Knotoid types		pdb	Title
S 3.1, 2.1		6mp6A	Cryo-em structure of the human neutral amino acid transporter asct2
S 3.1, 2.1		6scfA	A viral anti-crispr subverts type iii crispr immunity by rapid degradation of cyclic oligoadenylate
S 3.1, 2.1		6prmA	Crystal structure of apo pss1_19b
S 3.1, 2.1		5kgnA	1.95a resolution structure of independent phosphoglycerate mutase from c. elegans in complex with a macrocyclic peptide inhibitor (2d)
S 3.1, 2.1		5vpuA	Crystal structure of 2,3-bisphosphoglycerate-independent phosphoglycerate mutase bound to 3-phosphoglycerate, from acinetobacter baumannii
S 3.1, 2.1		3e2dA	The 1.4 a crystal structure of the large and cold-active vibrio sp. alkaline phosphatase
S 3.1, 2.1		3q3qA	Crystal structure of spap: an novel alkaline phosphatase from bacterium sphingomonas sp. strain bsar-1
S 3.1, 2.1		5xwkA	Crystal structure of spap, an alkaline phosphatase from sphingomonas in complex with inorganic phosphate
S 3.1, 2.1		5kglA	2.45a resolution structure of apo independent phosphoglycerate mutase from c. elegans (orthorhombic form)
S 3.1, 2.1		5xnuA	Structure of a catalytic domain of the colistin resistance enzyme
S 3.1, 2.1	₂	5tj3A	Crystal structure of wild type alkaline phosphatase pafa to 1.7a resolution
S 3.1, 2.1	₃	5znmA	Colicin d central domain and c-terminal trnase domain
S 3.1, 2.1		5g2vA	Structure of bt4656 in complex with its substrate d-glucosamine-2-n, 6-o-disulfate.
S 3.1, 2.1	₇	5ijsA	Crystal structure of autotaxin with orthovanadate bound as a trigonal bipyramidal intermediate analog
S 3.1, 2.1		3nkmA	Crystal structure of mouse autotaxin
S 3.1, 2.1	₃	3nkpA	Crystal structure of mouse autotaxin in complex with 18:1-lpa
S 3.1, 2.1	₂	3wavA	Crystal structure of autotaxin in complex with compound 10
S 3.1, 2.1	₂	3waxA	Crystal structure of autotaxin in complex with 3boa
S 3.1, 2.1		4b56A	Structure of ectonucleotide pyrophosphatase-phosphodiesterase-1 (npp1)
S 3.1, 2.1		3bdhA	Crystal structure of zinc-deficient wild-type e. coli alkaline phosphatase
S 3.1, 2.1	₄	4zg7A	Structural basis for inhibition of human autotaxin by four novel compounds
S 3.1, 2.1	₅	5k4pA	Catalytic domain of mcr-1 phosphoethanolamine transferase
S 3.1, 2.1	₅	5lrmA	Structure of di-zinc mcr-1 in p41212 space group
S 3.1, 2.1	₁	5m0sA	Structure-based evolution of a hybrid steroid series of autotaxin inhibitors
S 3.1, 2.1		5nj5A	E. coli microcin-processing metalloprotease tldd/e with phosphate bound
S 3.1, 2.1		5njaA	E. coli microcin-processing metalloprotease tldd/e with angiotensin analogue bound
S 3.1, 2.1		5tcdA	Human alkaline sphingomyelinase (enpp7) in complex with phosphocholine
S 3.1, 2.1		5udyA	Human alkaline sphingomyelinase (alk-smase, enpp7, npp7)
S 3.1, 2.1	₅	5yleA	Mcr-1 complex with ethanolamine (eta)
S 3.1, 2.1	₄	5ylfA	Mcr-1 complex with d-glucose
S 3.1, 2.1		1aliA	Alkaline phosphatase mutant (h412n)
S 3.1, 2.1		1aljA	Alkaline phosphatase mutant (h412n)
S 3.1, 2.1		1alkA	Reaction mechanism of alkaline phosphatase based on crystal structures. two metal ion catalysis
S 3.1, 2.1		1aniA	Alkaline phosphatase (d153h, k328h)
S 3.1, 2.1		1anjA	Alkaline phosphatase (k328h)
S 3.1, 2.1	₃	1aukA	Human arylsulfatase a
S 3.1, 2.1	₄	1b8jA	Alkaline phosphatase complexed with vanadate
S 3.1, 2.1	₅	1e2hA	The nucleoside binding site of herpes simplex type 1 thymidine kinase analyzed by x-ray crystallography
S 3.1, 2.1	₇	1e2iA	The nucleoside binding site of herpes simplex type 1 thymidine kinase analyzed by x-ray crystallography
S 3.1, 2.1	₇	1e2jA	The nucleoside binding site of herpes simplex type 1 thymidine kinase analyzed by x-ray crystallography
S 3.1, 2.1	₆	1e2kA	Kinetics and crystal structure of the wild-type and the engineered y101f mutant of herpes simplex virus type 1 thymidine kinase interacting with (north)-methanocarba-thymidine
S 3.1, 2.1	₆	1e2lA	Kinetics and crystal structure of the wild-type and the engineered y101f mutant of herpes simplex virus type 1 thymidine kinase interacting with (north)-methanocarba-thymidine
S 3.1, 2.1	₆	1e2mA	Hpt + hmtt
S 3.1, 2.1	₅	1e2nA	Hpt + hmtt
S 3.1, 2.1	₇	1e2pA	Thymidine kinase, dhbt
S 3.1, 2.1		1e3cP	Crystal structure of an arylsulfatase a mutant c69s soaked in synthetic substrate
S 3.1, 2.1		1ed8A	Structure of e. coli alkaline phosphatase inhibited by the inorganic phosphate at 1.75a resolution
S 3.1, 2.1		1ed9A	Structure of e. coli alkaline phosphatase without the inorganic phosphate at 1.75a resolution
S 3.1, 2.1		1elxA	E. coli alkaline phosphatase mutant (s102a)
S 3.1, 2.1		1elyA	E. coli alkaline phosphatase mutant (s102c)
S 3.1, 2.1		1elzA	E. coli alkaline phosphatase mutant (s102g)
S 3.1, 2.1		1ew2A	Crystal structure of a human phosphatase
S 3.1, 2.1		1ew8A	Alkaline phosphatase (e.c. 3.1.3.1) complex with phosphonoacetic acid
S 3.1, 2.1		1ew9A	Alkaline phosphatase (e.c. 3.1.3.1) complex with mercaptomethyl phosphonate
S 3.1, 2.1	₃	1fsuA	4-sulfatase (human)
S 3.1, 2.1	₅	1hdhA	Arylsulfatase from pseudomonas aeruginosa
S 3.1, 2.1	₅	1hjkA	Alkaline phosphatase mutant h331q
S 3.1, 2.1		1hqaA	Alkaline phosphatase (h412q)
S 3.1, 2.1		1k7hA	Crystal structure of shrimp alkaline phosphatase
S 3.1, 2.1		1kh4A	E. coli alkaline phosphatase mutant (d330n) in complex with phosphate
S 3.1, 2.1		1kh5A	E. coli alkaline phosphatase mutant (d330n) mimic of the transition states with aluminium fluoride
S 3.1, 2.1		1kh7A	E. coli alkaline phosphatase mutant (d153gd330n)
S 3.1, 2.1		1kh9A	E. coli alkaline phosphatase mutant (d153gd330n) complex with phosphate
S 3.1, 2.1		1khjA	E. coli alkaline phosphatase mutant (d153hd330n) mimic of the transition states with aluminium fluoride
S 3.1, 2.1		1khkA	E. coli alkaline phosphatase mutant (d153hd330n)
S 3.1, 2.1		1khlA	E. coli alkaline phosphatase mutant (d153hd330n) complex with phosphate
S 3.1, 2.1		1khnA	E. coli alkaline phosphatase mutant (d153hd330n) zinc form
S 3.1, 2.1	₃	1ki2A	Crystal structure of thymidine kinase from herpes simplex virus type i complexed with ganciclovir
S 3.1, 2.1	₄	1ki6A	Crystal structure of thymidine kinase from herpes simplex virus type i complexed with a 5-iodouracil anhydrohexitol nucleoside
S 3.1, 2.1	₄	1ki6B	Crystal structure of thymidine kinase from herpes simplex virus type i complexed with a 5-iodouracil anhydrohexitol nucleoside
S 3.1, 2.1	₇	1ki7A	Crystal structure of thymidine kinase from herpes simplex virus type i complexed with 5-iododeoxyuridine
S 3.1, 2.1	₄	1ki8A	Crystal structure of thymidine kinase from herpes simplex virus type i complexed with 5-bromovinyldeoxyuridine
S 3.1, 2.1	₅	1kimA	Crystal structure of thymidine kinase from herpes simplex virus type i complexed with deoxythymidine
S 3.1, 2.1	₄	1n2kA	Crystal structure of a covalent intermediate of endogenous human arylsulfatase a
S 3.1, 2.1		1n2mA	The s53a proenzyme structure of methanococcus jannaschii.
S 3.1, 2.1		1o98A	1.4a crystal structure of phosphoglycerate mutase from bacillus stearothermophilus complexed with 2-phosphoglycerate
S 3.1, 2.1		1o99A	Crystal structure of the s62a mutant of phosphoglycerate mutase from bacillus stearothermophilus complexed with 2-phosphoglycerate
S 3.1, 2.1		1ogcA	The structure of bacillus subtilis rbsd complexed with d-ribose
S 3.1, 2.1		1ogdA	The structure of bacillus subtilis rbsd complexed with d-ribose
S 3.1, 2.1		1ogeA	The structure of bacillus subtilis rbsd complexed with ribose 5-phosphate
S 3.1, 2.1		1ogfA	The structure of bacillus subtilis rbsd complexed with glycerol
S 3.1, 2.1	₃	1osnA	Crystal structure of varicella zoster virus thymidine kinase in complex with bvdu-mp and adp
S 3.1, 2.1	₄	1p49A	Structure of human placental estrone/dhea sulfatase
S 3.1, 2.1		1p6xA	Crystal structure of ehv4-tk complexed with thy and so4
S 3.1, 2.1	₃	1p72A	Crystal structure of ehv4-tk complexed with thy and adp
S 3.1, 2.1	₅	1p73A	Crystal structure of ehv4-tk complexed with tp4a
S 3.1, 2.1	₄	1p75A	Crystal structure of ehv4-tk complexed with tp5a
S 3.1, 2.1	₆	1p7cA	Crystal structure of hsv1-tk complexed with tp5a
S 3.1, 2.1	₅	1qhiA	Herpes simplex virus type-i thymidine kinase complexed with a novel non-substrate inhibitor, 9-(4-hydroxybutyl)-n2-phenylguanine
S 3.1, 2.1		1rh1A	Crystal structure of the cytotoxic bacterial protein colicin b at 2.5 a resolution
S 3.1, 2.1		1shnA	Crystal structure of shrimp alkaline phosphatase with phosphate bound
S 3.1, 2.1		1shqA	Crystal structure of shrimp alkaline phosphatase with magnesium in m3
S 3.1, 2.1		2anhA	Alkaline phosphatase (d153h)
S 3.1, 2.1	₃	2axcA	Crystal structure of cole7 translocation domain
S 3.1, 2.1		2b5uA	Crystal structure of colicin e3 v206c mutant in complex with its immunity protein
S 3.1, 2.1		2g9yA	Structure of s102t e. coli alkaline phosphatase in presence of phosphate at 2.00 a resolution
S 3.1, 2.1	₅	2ga3A	Structure of s102t e. coli alkaline phosphatase-phosphate intermediate at 2.20a resolution
S 3.1, 2.1	₆	2glqA	X-ray structure of human alkaline phosphatase in complex with strontium
S 3.1, 2.1		2gsnA	Structure of xac nucleotide pyrophosphatase/phosphodiesterase
S 3.1, 2.1		2gsoA	Structure of xac nucleotide pyrophosphatase/phosphodiesterase in complex with vanadate
S 3.1, 2.1	₂	2hjnA	Structural and functional analysis of saccharomyces cerevisiae mob1
S 3.1, 2.1	₁	2iucA	Structure of alkaline phosphatase from the antarctic bacterium tab5
S 3.1, 2.1	₁	2iucB	Structure of alkaline phosphatase from the antarctic bacterium tab5
S 3.1, 2.1	₅	2ki5A	Herpes simplex type-1 thymidine kinase in complex with the drug aciclovir at 1.9a resolution
S 3.1, 2.1	₁₀	2nwlA	Crystal structure of gltph in complex with l-asp
S 3.1, 2.1		2nwwA	Crystal structure of gltph in complex with tboa
S 3.1, 2.1	₁₀	2nwxA	Crystal structure of gltph in complex with l-aspartate and sodium ions
S 3.1, 2.1		2ob5A	Crystal structure of protein atu2016, putative sugar binding protein
S 3.1, 2.1		2qzuA	Crystal structure of the putative sulfatase yidj from bacteroides fragilis. northeast structural genomics consortium target bfr123
S 3.1, 2.1		2rh6A	Structure of xac npp for evaluation of refinement methodology
S 3.1, 2.1	₅	2vtkA	Thymidine kinase from herpes simplex virus type 1 in complex with adp and deoxythymidine
S 3.1, 2.1		2w5qA	Structure-based mechanism of lipoteichoic acid synthesis by staphylococcus aureus ltas.
S 3.1, 2.1		2w5rA	Structure-based mechanism of lipoteichoic acid synthesis by staphylococcus aureus ltas.
S 3.1, 2.1		2w5sA	Structure-based mechanism of lipoteichoic acid synthesis by staphylococcus aureus ltas.
S 3.1, 2.1		2w5tA	Structure-based mechanism of lipoteichoic acid synthesis by staphylococcus aureus ltas.
S 3.1, 2.1	₄	2w5wA	Structure of tab5 alkaline phosphatase mutant his 135 asp with zn bound in the m3 site.
S 3.1, 2.1	₃	2w5xA	Structure of tab5 alkaline phosphatase mutant his 135 glu with mg bound in the m3 site.
S 3.1, 2.1	₃	2w8dA	Distinct and essential morphogenic functions for wall- and lipo-teichoic acids in bacillus subtilis
S 3.1, 2.1	₇	2wcvA	Crystal structure of bacterial fucu
S 3.1, 2.1		2x98A	H.salinarum alkaline phosphatase
S 3.1, 2.1	₁	2xr9A	Crystal structure of autotaxin (enpp2)
S 3.1, 2.1	₂	2xrgA	Crystal structure of autotaxin (enpp2) in complex with the ha155 boronic acid inhibitor
S 3.1, 2.1	₂	2zktA	Structure of ph0037 protein from pyrococcus horikoshii
S 3.1, 2.1	₇	3bdfA	Crystal structure of metal-free e. coli alkaline phosphatase (t155v)
S 3.1, 2.1	₇	3bdgA	Crystal structure of wild-type/t155v mixed dimer of e. coli alkaline phosphatase
S 3.1, 2.1	₅	3bdgB	Crystal structure of wild-type/t155v mixed dimer of e. coli alkaline phosphatase
S 3.1, 2.1		3cmrA	E. coli alkaline phosphatase mutant r166s in complex with phosphate
S 3.1, 2.1		3dycA	Structure of e322y alkaline phosphatase in complex with inorganic phosphate
S 3.1, 2.1		3e7nA	Crystal structure of d-ribose high-affinity transport system from salmonella typhimurium lt2
S 3.1, 2.1		3ed4A	Crystal structure of putative arylsulfatase from escherichia coli
S 3.1, 2.1	₆	3f0tA	Crystal structure of thymidine kinase from herpes simplex virus type 1 in complex with n-methyl-dhbt
S 3.1, 2.1		3igyB	Crystal structures of leishmania mexicana phosphoglycerate mutase at high cobalt concentrations
S 3.1, 2.1		3igzB	Crystal structures of leishmania mexicana phosphoglycerate mutase at low cobalt concentration
S 3.1, 2.1		3kbcA	Crystal structure of gltph k55c-a364c mutant crosslinked with divalent mercury
S 3.1, 2.1		3lxqA	The crystal structure of a protein in the alkaline phosphatase superfamily from vibrio parahaemolyticus to 1.95a
S 3.1, 2.1	₃	3m8yA	Phosphopentomutase from bacillus cereus after glucose-1,6-bisphosphate activation
S 3.1, 2.1	₃	3m8zA	Phosphopentomutase from bacillus cereus bound with ribose-5-phosphate
S 3.1, 2.1	₃	3mk0A	Refinement of placental alkaline phosphatase complexed with nitrophenyl
S 3.1, 2.1	₄	3mk1A	Refinement of placental alkaline phosphatase complexed with nitrophenyl
S 3.1, 2.1	₅	3mk2A	Placental alkaline phosphatase complexed with phe
S 3.1, 2.1		3mvkA	The crystal structure of fucu from bifidobacterium longum to 1.65a
S 3.1, 2.1	₁	3nkqA	Crystal structure of mouse autotaxin in complex with 18:3-lpa
S 3.1, 2.1	₁	3nkrA	Crystal structure of mouse autotaxin in complex with 22:6-lpa
S 3.1, 2.1		3nvlA	Crystal structure of phosphoglycerate mutase from trypanosoma brucei
S 3.1, 2.1	₃	3ot9A	Phosphopentomutase from bacillus cereus bound to glucose-1,6-bisphosphate
S 3.1, 2.1		3p13A	Complex structure of d-ribose pyranase sa240 with d-ribose
S 3.1, 2.1		3rdpA	Crystal structure of thymidine kinase from herpes simplex virus type 1 in complex with n-methyl-fhbt
S 3.1, 2.1		3szyA	Crystal structure of phosphonoacetate hydrolase from sinorhizobium meliloti 1021 in apo form
S 3.1, 2.1		3szzA	Crystal structure of phosphonoacetate hydrolase from sinorhizobium meliloti 1021 in complex with acetate
S 3.1, 2.1		3t00A	Crystal structure of phosphonoacetate hydrolase from sinorhizobium meliloti 1021 in complex with vanadate

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