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id
stringlengths
15
19
document_id
stringlengths
15
19
passages
list
entities
list
events
list
coreferences
list
relations
list
split_0_train_0
split_0_train_0
[ { "id": "split_0_train_0_passage", "type": "progene_text", "text": [ "NMD3 encodes an essential cytoplasmic protein required for stable 60S ribosomal subunits in Saccharomyces cerevisiae ." ], "offsets": [ [ 0, 118 ] ] } ]
[ { "id": "split_0_train_0_entity", "type": "progene_text", "text": [ "NMD3" ], "offsets": [ [ 0, 4 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_1
split_0_train_1
[ { "id": "split_0_train_1_passage", "type": "progene_text", "text": [ "A mutation in NMD3 was found to be lethal in the absence of XRN1 , which encodes the major cytoplasmic exoribonuclease responsible for mRNA turnover ." ], "offsets": [ [ 0, 150 ] ] } ]
[]
[]
[]
[]
split_0_train_2
split_0_train_2
[ { "id": "split_0_train_2_passage", "type": "progene_text", "text": [ "Molecular genetic analysis of NMD3 revealed that it is an essential gene required for stable 60S ribosomal subunits ." ], "offsets": [ [ 0, 117 ] ] } ]
[ { "id": "split_0_train_1_entity", "type": "progene_text", "text": [ "NMD3" ], "offsets": [ [ 30, 34 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_3
split_0_train_3
[ { "id": "split_0_train_3_passage", "type": "progene_text", "text": [ "Cells bearing a temperature - sensitive allele of NMD3 had decreased levels of 60S subunits at the nonpermissive temperature which resulted in the formation of half - mer polysomes ." ], "offsets": [ [ 0, 182 ] ] } ]
[ { "id": "split_0_train_2_entity", "type": "progene_text", "text": [ "NMD3" ], "offsets": [ [ 50, 54 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_4
split_0_train_4
[ { "id": "split_0_train_4_passage", "type": "progene_text", "text": [ "Pulse - chase analysis of rRNA biogenesis indicated that 25S rRNA was made and processed with kinetics similar to wild - type kinetics ." ], "offsets": [ [ 0, 136 ] ] } ]
[]
[]
[]
[]
split_0_train_5
split_0_train_5
[ { "id": "split_0_train_5_passage", "type": "progene_text", "text": [ "However , the mature RNA was rapidly degraded , with a half - life of 4 min ." ], "offsets": [ [ 0, 77 ] ] } ]
[]
[]
[]
[]
split_0_train_6
split_0_train_6
[ { "id": "split_0_train_6_passage", "type": "progene_text", "text": [ "Nmd3p fractionated as a cytoplasmic protein and sedimented in the position of free 60S subunits in sucrose gradients ." ], "offsets": [ [ 0, 118 ] ] } ]
[ { "id": "split_0_train_3_entity", "type": "progene_text", "text": [ "Nmd3p" ], "offsets": [ [ 0, 5 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_7
split_0_train_7
[ { "id": "split_0_train_7_passage", "type": "progene_text", "text": [ "These results suggest that Nmd3p is a cytoplasmic factor required for a late cytoplasmic assembly step of the 60S subunit but is not a ribosomal protein ." ], "offsets": [ [ 0, 154 ] ] } ]
[ { "id": "split_0_train_4_entity", "type": "progene_text", "text": [ "Nmd3p" ], "offsets": [ [ 27, 32 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_8
split_0_train_8
[ { "id": "split_0_train_8_passage", "type": "progene_text", "text": [ "Putative orthologs of Nmd3p exist in Drosophila , in nematodes , and in archaebacteria but not in eubacteria ." ], "offsets": [ [ 0, 110 ] ] } ]
[ { "id": "split_0_train_5_entity", "type": "progene_text", "text": [ "Nmd3p" ], "offsets": [ [ 22, 27 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_9
split_0_train_9
[ { "id": "split_0_train_9_passage", "type": "progene_text", "text": [ "The Nmd3 protein sequence does not contain readily recognizable motifs of known function ." ], "offsets": [ [ 0, 90 ] ] } ]
[ { "id": "split_0_train_6_entity", "type": "progene_text", "text": [ "Nmd3" ], "offsets": [ [ 4, 8 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_10
split_0_train_10
[ { "id": "split_0_train_10_passage", "type": "progene_text", "text": [ "However , these proteins all have an amino - terminal domain containing four repeats of Cx2C , reminiscent of zinc - binding proteins , implicated in nucleic acid binding or protein oligomerization ." ], "offsets": [ [ 0, 199 ] ] } ]
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[]
[]
[]
split_0_train_11
split_0_train_11
[ { "id": "split_0_train_11_passage", "type": "progene_text", "text": [ "Skeletal muscle type ryanodine receptor is involved in calcium signaling in human B lymphocytes ." ], "offsets": [ [ 0, 97 ] ] } ]
[ { "id": "split_0_train_7_entity", "type": "progene_text", "text": [ "Skeletal muscle type ryanodine receptor" ], "offsets": [ [ 0, 39 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_12
split_0_train_12
[ { "id": "split_0_train_12_passage", "type": "progene_text", "text": [ "The regulation of intracellular free Ca2+ concentration ( [ Ca2+ ] i ) in B cells remains poorly understood and is presently explained almost solely by inositol 1,4,5-triphosphate ( IP3 ) - mediated Ca2+ release , followed by activation of a store - operated channel mechanism ." ], "offsets": [ [ 0, 278 ] ] } ]
[]
[]
[]
[]
split_0_train_13
split_0_train_13
[ { "id": "split_0_train_13_passage", "type": "progene_text", "text": [ "In fact , there are reports indicating that IP3 production does not always correlate with the magnitude of Ca2+ release ." ], "offsets": [ [ 0, 121 ] ] } ]
[]
[]
[]
[]
split_0_train_14
split_0_train_14
[ { "id": "split_0_train_14_passage", "type": "progene_text", "text": [ "We demonstrate here that human B cells express a ryanodine receptor ( RYR ) that functions as a Ca2+ release channel during the B cell antigen receptor ( BCR ) - stimulated Ca2+ signaling process ." ], "offsets": [ [ 0, 197 ] ] } ]
[ { "id": "split_0_train_8_entity", "type": "progene_text", "text": [ "ryanodine receptor" ], "offsets": [ [ 49, 67 ] ], "normalized": [] }, { "id": "split_0_train_9_entity", "type": "progene_text", "text": [ "RYR" ], "offsets": [ [ 70, 73 ] ], "normalized": [] }, { "id": "split_0_train_10_entity", "type": "progene_text", "text": [ "B cell antigen receptor" ], "offsets": [ [ 128, 151 ] ], "normalized": [] }, { "id": "split_0_train_11_entity", "type": "progene_text", "text": [ "BCR" ], "offsets": [ [ 154, 157 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_15
split_0_train_15
[ { "id": "split_0_train_15_passage", "type": "progene_text", "text": [ "Immunoblotting studies showed that both human primary CD19 ( + ) B and DAKIKI cells express a 565 - kDa immunoreactive protein that is indistinguishable in molecular size and immunoreactivity from the RYR ." ], "offsets": [ [ 0, 206 ] ] } ]
[ { "id": "split_0_train_12_entity", "type": "progene_text", "text": [ "CD19" ], "offsets": [ [ 54, 58 ] ], "normalized": [] }, { "id": "split_0_train_13_entity", "type": "progene_text", "text": [ "RYR" ], "offsets": [ [ 201, 204 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_16
split_0_train_16
[ { "id": "split_0_train_16_passage", "type": "progene_text", "text": [ "Selective reverse transcription - polymerase chain reaction , restriction fragment length polymorphism , and sequencing of cloned cDNA indicated that the major isoform of the RYR expressed in primary CD19 ( + ) B and DAKIKI cells is identical to the skeletal muscle type ( RYR1 ) ." ], "offsets": [ [ 0, 281 ] ] } ]
[ { "id": "split_0_train_14_entity", "type": "progene_text", "text": [ "RYR" ], "offsets": [ [ 175, 178 ] ], "normalized": [] }, { "id": "split_0_train_15_entity", "type": "progene_text", "text": [ "CD19" ], "offsets": [ [ 200, 204 ] ], "normalized": [] }, { "id": "split_0_train_16_entity", "type": "progene_text", "text": [ "skeletal muscle type" ], "offsets": [ [ 250, 270 ] ], "normalized": [] }, { "id": "split_0_train_17_entity", "type": "progene_text", "text": [ "RYR1" ], "offsets": [ [ 273, 277 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_17
split_0_train_17
[ { "id": "split_0_train_17_passage", "type": "progene_text", "text": [ "Saturation analysis of [3H]ryanodine binding yielded Bmax = 150 fmol / mg of protein and Kd = 110 nM in DAKIKI cells ." ], "offsets": [ [ 0, 118 ] ] } ]
[]
[]
[]
[]
split_0_train_18
split_0_train_18
[ { "id": "split_0_train_18_passage", "type": "progene_text", "text": [ "In fluo-3-loaded CD19 ( + ) B and DAKIKI cells , 4-chloro-m-cresol , a potent activator of Ca2+ release mediated by the ryanodine - sensitive Ca2+ release channel , induced Ca2+ release in a dose - dependent and ryanodine - sensitive fashion ." ], "offsets": [ [ 0, 243 ] ] } ]
[ { "id": "split_0_train_18_entity", "type": "progene_text", "text": [ "CD19" ], "offsets": [ [ 17, 21 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_19
split_0_train_19
[ { "id": "split_0_train_19_passage", "type": "progene_text", "text": [ "Furthermore , BCR - mediated Ca2+ release in CD19 ( + ) B cells was significantly altered by 4-chloro-m-cresol and ryanodine ." ], "offsets": [ [ 0, 126 ] ] } ]
[ { "id": "split_0_train_19_entity", "type": "progene_text", "text": [ "BCR" ], "offsets": [ [ 14, 17 ] ], "normalized": [] }, { "id": "split_0_train_20_entity", "type": "progene_text", "text": [ "CD19" ], "offsets": [ [ 45, 49 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_20
split_0_train_20
[ { "id": "split_0_train_20_passage", "type": "progene_text", "text": [ "These results indicate that RYR1 functions as a Ca2+ release channel during BCR - stimulated Ca2+ signaling and suggest that complex Ca2+ signals that control the cellular activities of B cells may be generated by cooperation of the IP3 receptor and RYR1 ." ], "offsets": [ [ 0, 256 ] ] } ]
[ { "id": "split_0_train_21_entity", "type": "progene_text", "text": [ "RYR1" ], "offsets": [ [ 28, 32 ] ], "normalized": [] }, { "id": "split_0_train_22_entity", "type": "progene_text", "text": [ "BCR" ], "offsets": [ [ 76, 79 ] ], "normalized": [] }, { "id": "split_0_train_23_entity", "type": "progene_text", "text": [ "IP3 receptor" ], "offsets": [ [ 233, 245 ] ], "normalized": [] }, { "id": "split_0_train_24_entity", "type": "progene_text", "text": [ "RYR1" ], "offsets": [ [ 250, 254 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_21
split_0_train_21
[ { "id": "split_0_train_21_passage", "type": "progene_text", "text": [ "Myofibroblasts in schistosomal portal fibrosis of man ." ], "offsets": [ [ 0, 55 ] ] } ]
[]
[]
[]
[]
split_0_train_22
split_0_train_22
[ { "id": "split_0_train_22_passage", "type": "progene_text", "text": [ "Myofibroblasts , cells with intermediate features between smooth muscle cells and fibroblasts , have been described as an important cellular component of schistosomal portal fibrosis ." ], "offsets": [ [ 0, 184 ] ] } ]
[]
[]
[]
[]
split_0_train_23
split_0_train_23
[ { "id": "split_0_train_23_passage", "type": "progene_text", "text": [ "The origin , distribution and fate of myofibroblasts were investigated by means of light , fluorescent , immunoenzymatic and ultrastructural techniques in wedge liver biopsies from 68 patients with the hepatosplenic form of schistosomiasis ." ], "offsets": [ [ 0, 241 ] ] } ]
[]
[]
[]
[]
split_0_train_24
split_0_train_24
[ { "id": "split_0_train_24_passage", "type": "progene_text", "text": [ "Results demonstrated that the presence of myofibroblasts varied considerably from case to case and was always related to smooth muscle cell dispersion , which occurred around medium - sized damaged portal vein branches ." ], "offsets": [ [ 0, 220 ] ] } ]
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[]
[]
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split_0_train_25
split_0_train_25
[ { "id": "split_0_train_25_passage", "type": "progene_text", "text": [ "By sequential observation of several cases , it was evident that myofibroblasts derived by differentiation of vascular smooth muscle and gradually tended to disappear , some of them further differentiating into fibroblasts ." ], "offsets": [ [ 0, 224 ] ] } ]
[]
[]
[]
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split_0_train_26
split_0_train_26
[ { "id": "split_0_train_26_passage", "type": "progene_text", "text": [ "Thus , in schistosomal pipestem fibrosis myofibroblasts appear as transient cells , focally accumulated around damaged portal vein branches , and do not seem to have by themselves any important participation in the pathogenesis of hepatosplenic schistosomiasis ." ], "offsets": [ [ 0, 262 ] ] } ]
[]
[]
[]
[]
split_0_train_27
split_0_train_27
[ { "id": "split_0_train_27_passage", "type": "progene_text", "text": [ "Ski is a component of the histone deacetylase complex required for transcriptional repression by Mad and thyroid hormone receptor ." ], "offsets": [ [ 0, 131 ] ] } ]
[ { "id": "split_0_train_25_entity", "type": "progene_text", "text": [ "Ski" ], "offsets": [ [ 0, 3 ] ], "normalized": [] }, { "id": "split_0_train_26_entity", "type": "progene_text", "text": [ "histone deacetylase" ], "offsets": [ [ 26, 45 ] ], "normalized": [] }, { "id": "split_0_train_27_entity", "type": "progene_text", "text": [ "Mad" ], "offsets": [ [ 97, 100 ] ], "normalized": [] }, { "id": "split_0_train_28_entity", "type": "progene_text", "text": [ "thyroid hormone receptor" ], "offsets": [ [ 105, 129 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_28
split_0_train_28
[ { "id": "split_0_train_28_passage", "type": "progene_text", "text": [ "The N-CoR / SMRT complex containing mSin3 and histone deacetylase ( HDAC ) mediates transcriptional repression by nuclear hormone receptors and Mad ." ], "offsets": [ [ 0, 149 ] ] } ]
[ { "id": "split_0_train_29_entity", "type": "progene_text", "text": [ "N-CoR" ], "offsets": [ [ 4, 9 ] ], "normalized": [] }, { "id": "split_0_train_30_entity", "type": "progene_text", "text": [ "SMRT" ], "offsets": [ [ 12, 16 ] ], "normalized": [] }, { "id": "split_0_train_31_entity", "type": "progene_text", "text": [ "mSin3" ], "offsets": [ [ 36, 41 ] ], "normalized": [] }, { "id": "split_0_train_32_entity", "type": "progene_text", "text": [ "histone deacetylase" ], "offsets": [ [ 46, 65 ] ], "normalized": [] }, { "id": "split_0_train_33_entity", "type": "progene_text", "text": [ "HDAC" ], "offsets": [ [ 68, 72 ] ], "normalized": [] }, { "id": "split_0_train_34_entity", "type": "progene_text", "text": [ "nuclear hormone receptors" ], "offsets": [ [ 114, 139 ] ], "normalized": [] }, { "id": "split_0_train_35_entity", "type": "progene_text", "text": [ "Mad" ], "offsets": [ [ 144, 147 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_29
split_0_train_29
[ { "id": "split_0_train_29_passage", "type": "progene_text", "text": [ "The proteins encoded by the ski proto - oncogene family directly bind to N-CoR / SMRT and mSin3A , and forms a complex with HDAC ." ], "offsets": [ [ 0, 130 ] ] } ]
[ { "id": "split_0_train_36_entity", "type": "progene_text", "text": [ "ski proto - oncogene family" ], "offsets": [ [ 28, 55 ] ], "normalized": [] }, { "id": "split_0_train_37_entity", "type": "progene_text", "text": [ "N-CoR" ], "offsets": [ [ 73, 78 ] ], "normalized": [] }, { "id": "split_0_train_38_entity", "type": "progene_text", "text": [ "SMRT" ], "offsets": [ [ 81, 85 ] ], "normalized": [] }, { "id": "split_0_train_39_entity", "type": "progene_text", "text": [ "mSin3A" ], "offsets": [ [ 90, 96 ] ], "normalized": [] }, { "id": "split_0_train_40_entity", "type": "progene_text", "text": [ "HDAC" ], "offsets": [ [ 124, 128 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_30
split_0_train_30
[ { "id": "split_0_train_30_passage", "type": "progene_text", "text": [ "c-Ski and its related gene product Sno are required for transcriptional repression by Mad and thyroid hormone receptor ( TRbeta ) ." ], "offsets": [ [ 0, 131 ] ] } ]
[ { "id": "split_0_train_41_entity", "type": "progene_text", "text": [ "c-Ski" ], "offsets": [ [ 0, 5 ] ], "normalized": [] }, { "id": "split_0_train_42_entity", "type": "progene_text", "text": [ "Sno" ], "offsets": [ [ 35, 38 ] ], "normalized": [] }, { "id": "split_0_train_43_entity", "type": "progene_text", "text": [ "Mad" ], "offsets": [ [ 86, 89 ] ], "normalized": [] }, { "id": "split_0_train_44_entity", "type": "progene_text", "text": [ "thyroid hormone receptor" ], "offsets": [ [ 94, 118 ] ], "normalized": [] }, { "id": "split_0_train_45_entity", "type": "progene_text", "text": [ "TRbeta" ], "offsets": [ [ 121, 127 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_31
split_0_train_31
[ { "id": "split_0_train_31_passage", "type": "progene_text", "text": [ "The oncogenic form , v-Ski , which lacks the mSin3A - binding domain , acts in a dominant - negative fashion , and abrogates transcriptional repression by Mad and TRbeta ." ], "offsets": [ [ 0, 171 ] ] } ]
[ { "id": "split_0_train_46_entity", "type": "progene_text", "text": [ "v-Ski" ], "offsets": [ [ 21, 26 ] ], "normalized": [] }, { "id": "split_0_train_47_entity", "type": "progene_text", "text": [ "mSin3A" ], "offsets": [ [ 45, 51 ] ], "normalized": [] }, { "id": "split_0_train_48_entity", "type": "progene_text", "text": [ "Mad" ], "offsets": [ [ 155, 158 ] ], "normalized": [] }, { "id": "split_0_train_49_entity", "type": "progene_text", "text": [ "TRbeta" ], "offsets": [ [ 163, 169 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_32
split_0_train_32
[ { "id": "split_0_train_32_passage", "type": "progene_text", "text": [ "In ski - deficient mouse embryos , the ornithine decarboxylase gene , whose expression is normally repressed by Mad - Max , is expressed ectopically ." ], "offsets": [ [ 0, 150 ] ] } ]
[ { "id": "split_0_train_50_entity", "type": "progene_text", "text": [ "ski" ], "offsets": [ [ 3, 6 ] ], "normalized": [] }, { "id": "split_0_train_51_entity", "type": "progene_text", "text": [ "ornithine decarboxylase" ], "offsets": [ [ 39, 62 ] ], "normalized": [] }, { "id": "split_0_train_52_entity", "type": "progene_text", "text": [ "Mad" ], "offsets": [ [ 112, 115 ] ], "normalized": [] }, { "id": "split_0_train_53_entity", "type": "progene_text", "text": [ "Max" ], "offsets": [ [ 118, 121 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_33
split_0_train_33
[ { "id": "split_0_train_33_passage", "type": "progene_text", "text": [ "These results show that Ski is a component of the HDAC complex and that Ski is required for the transcriptional repression mediated by this complex ." ], "offsets": [ [ 0, 149 ] ] } ]
[ { "id": "split_0_train_54_entity", "type": "progene_text", "text": [ "Ski" ], "offsets": [ [ 24, 27 ] ], "normalized": [] }, { "id": "split_0_train_55_entity", "type": "progene_text", "text": [ "HDAC" ], "offsets": [ [ 50, 54 ] ], "normalized": [] }, { "id": "split_0_train_56_entity", "type": "progene_text", "text": [ "Ski" ], "offsets": [ [ 72, 75 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_34
split_0_train_34
[ { "id": "split_0_train_34_passage", "type": "progene_text", "text": [ "The involvement of c-Ski in the HDAC complex indicates that the function of the HDAC complex is important for oncogenesis ." ], "offsets": [ [ 0, 123 ] ] } ]
[ { "id": "split_0_train_57_entity", "type": "progene_text", "text": [ "c-Ski" ], "offsets": [ [ 19, 24 ] ], "normalized": [] }, { "id": "split_0_train_58_entity", "type": "progene_text", "text": [ "HDAC" ], "offsets": [ [ 32, 36 ] ], "normalized": [] }, { "id": "split_0_train_59_entity", "type": "progene_text", "text": [ "HDAC" ], "offsets": [ [ 80, 84 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_35
split_0_train_35
[ { "id": "split_0_train_35_passage", "type": "progene_text", "text": [ "Physical and transcriptional map of a 3-Mb region of mouse chromosome 1 containing the gene for the neural tube defect mutant loop - tail ( Lp ) ." ], "offsets": [ [ 0, 146 ] ] } ]
[]
[]
[]
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split_0_train_36
split_0_train_36
[ { "id": "split_0_train_36_passage", "type": "progene_text", "text": [ "The Lp mouse mutant provides a model for the severe human neural tube defect ( NTD ) , cranio - rachischisis ." ], "offsets": [ [ 0, 110 ] ] } ]
[]
[]
[]
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split_0_train_37
split_0_train_37
[ { "id": "split_0_train_37_passage", "type": "progene_text", "text": [ "To identify the Lp gene , a positional cloning approach has been adopted ." ], "offsets": [ [ 0, 74 ] ] } ]
[]
[]
[]
[]
split_0_train_38
split_0_train_38
[ { "id": "split_0_train_38_passage", "type": "progene_text", "text": [ "Previously , linkage analysis in a large intraspecific backcross was used to map the Lp locus to distal mouse chromosome 1 ." ], "offsets": [ [ 0, 124 ] ] } ]
[]
[]
[]
[]
split_0_train_39
split_0_train_39
[ { "id": "split_0_train_39_passage", "type": "progene_text", "text": [ "Here we report a detailed physical map of this region ." ], "offsets": [ [ 0, 55 ] ] } ]
[]
[]
[]
[]
split_0_train_40
split_0_train_40
[ { "id": "split_0_train_40_passage", "type": "progene_text", "text": [ "The interval surrounding Lp has been cloned in a yeast artificial chromosome ( YAC ) contig consisting of 63 clones spanning approximately 3.2 Mb ." ], "offsets": [ [ 0, 147 ] ] } ]
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[]
[]
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split_0_train_41
split_0_train_41
[ { "id": "split_0_train_41_passage", "type": "progene_text", "text": [ "Fifty sequence tagged sites ( STSs ) have been used to construct the contig and establish marker order across the interval ." ], "offsets": [ [ 0, 124 ] ] } ]
[]
[]
[]
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split_0_train_42
split_0_train_42
[ { "id": "split_0_train_42_passage", "type": "progene_text", "text": [ "Based on the high level of conserved synteny between distal mouse chromosome 1 and human 1q21 - q24 , many of these STSs were designed from expressed sequences identified by cross - screening human and mouse databases of expressed sequence tags ." ], "offsets": [ [ 0, 246 ] ] } ]
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[]
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split_0_train_43
split_0_train_43
[ { "id": "split_0_train_43_passage", "type": "progene_text", "text": [ "Added to other known genes in the region , a total of 29 genes were located and ordered within the contig ." ], "offsets": [ [ 0, 107 ] ] } ]
[]
[]
[]
[]
split_0_train_44
split_0_train_44
[ { "id": "split_0_train_44_passage", "type": "progene_text", "text": [ "Seven novel polymorphisms were identified within the region , allowing refinement of the genetic map and a reduction in the size of the physical interval containing the Lp gene ." ], "offsets": [ [ 0, 178 ] ] } ]
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split_0_train_45
split_0_train_45
[ { "id": "split_0_train_45_passage", "type": "progene_text", "text": [ "The Lp interval , between D1Mit113 and Tagln2 , can be spanned by two nonchimeric overlapping YACs that define a physical distance of approximately 1 Mb ." ], "offsets": [ [ 0, 154 ] ] } ]
[]
[]
[]
[]
split_0_train_46
split_0_train_46
[ { "id": "split_0_train_46_passage", "type": "progene_text", "text": [ "Within this region , 10 potential candidate genes have been mapped ." ], "offsets": [ [ 0, 68 ] ] } ]
[]
[]
[]
[]
split_0_train_47
split_0_train_47
[ { "id": "split_0_train_47_passage", "type": "progene_text", "text": [ "The materials and genes described here will provide a resource for the identification and further study of the mutated Lp gene that causes this severe neural tube defect and will provide candidates for other defects known to map to the homologous region on human chromosome 1q ." ], "offsets": [ [ 0, 278 ] ] } ]
[]
[]
[]
[]
split_0_train_48
split_0_train_48
[ { "id": "split_0_train_48_passage", "type": "progene_text", "text": [ "The SH2 domain - containing inositol 5'-phosphatase ( SHIP ) recruits the p85 subunit of phosphoinositide 3-kinase during FcgammaRIIb1 - mediated inhibition of B cell receptor signaling ." ], "offsets": [ [ 0, 187 ] ] } ]
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[]
[]
[]
split_0_train_49
split_0_train_49
[ { "id": "split_0_train_49_passage", "type": "progene_text", "text": [ "Coligation of FcgammaRIIb1 with the B cell receptor ( BCR ) or FcepsilonRI on mast cells inhibits B cell or mast cell activation ." ], "offsets": [ [ 0, 130 ] ] } ]
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[]
[]
[]
split_0_train_50
split_0_train_50
[ { "id": "split_0_train_50_passage", "type": "progene_text", "text": [ "Activity of the inositol phosphatase SHIP is required for this negative signal ." ], "offsets": [ [ 0, 80 ] ] } ]
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[]
[]
[]
split_0_train_51
split_0_train_51
[ { "id": "split_0_train_51_passage", "type": "progene_text", "text": [ "In vitro , SHIP catalyzes the conversion of the phosphoinositide 3-kinase ( PI3K ) product phosphatidylinositol 3,4 , 5-trisphosphate ( PIP3 ) into phosphatidylinositol 3,4-bisphosphate ." ], "offsets": [ [ 0, 187 ] ] } ]
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[]
[]
[]
split_0_train_52
split_0_train_52
[ { "id": "split_0_train_52_passage", "type": "progene_text", "text": [ "Recent data demonstrate that coligation of FcgammaRIIb1 with BCR inhibits PIP3 - dependent Btk ( Bruton 's tyrosine kinase ) activation and the Btk - dependent generation of inositol trisphosphate that regulates sustained calcium influx ." ], "offsets": [ [ 0, 238 ] ] } ]
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[]
[]
[]
split_0_train_53
split_0_train_53
[ { "id": "split_0_train_53_passage", "type": "progene_text", "text": [ "In this study , we provide evidence that coligation of FcgammaRIIb1 with BCR induces binding of PI3K to SHIP ." ], "offsets": [ [ 0, 110 ] ] } ]
[ { "id": "split_0_train_79_entity", "type": "progene_text", "text": [ "FcgammaRIIb1" ], "offsets": [ [ 55, 67 ] ], "normalized": [] }, { "id": "split_0_train_80_entity", "type": "progene_text", "text": [ "BCR" ], "offsets": [ [ 73, 76 ] ], "normalized": [] }, { "id": "split_0_train_81_entity", "type": "progene_text", "text": [ "PI3K" ], "offsets": [ [ 96, 100 ] ], "normalized": [] }, { "id": "split_0_train_82_entity", "type": "progene_text", "text": [ "SHIP" ], "offsets": [ [ 104, 108 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_54
split_0_train_54
[ { "id": "split_0_train_54_passage", "type": "progene_text", "text": [ "This interaction is mediated by the binding of the SH2 domains of the p85 subunit of PI3K to a tyrosine - based motif in the C - terminal region of SHIP ." ], "offsets": [ [ 0, 154 ] ] } ]
[ { "id": "split_0_train_83_entity", "type": "progene_text", "text": [ "p85 subunit of PI3K" ], "offsets": [ [ 70, 89 ] ], "normalized": [] }, { "id": "split_0_train_84_entity", "type": "progene_text", "text": [ "SHIP" ], "offsets": [ [ 148, 152 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_55
split_0_train_55
[ { "id": "split_0_train_55_passage", "type": "progene_text", "text": [ "Furthermore , the generation of phosphatidylinositol 3,4-bisphosphate was only partially reduced during coligation of BCR with FcgammaRIIb1 despite a drastic reduction in PIP3 ." ], "offsets": [ [ 0, 177 ] ] } ]
[ { "id": "split_0_train_85_entity", "type": "progene_text", "text": [ "BCR" ], "offsets": [ [ 118, 121 ] ], "normalized": [] }, { "id": "split_0_train_86_entity", "type": "progene_text", "text": [ "FcgammaRIIb1" ], "offsets": [ [ 127, 139 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_56
split_0_train_56
[ { "id": "split_0_train_56_passage", "type": "progene_text", "text": [ "In contrast to the complete inhibition of Tec kinase - dependent calcium signaling , activation of the serine / threonine kinase Akt was partially preserved during BCR and FcgammaRIIb1 coligation ." ], "offsets": [ [ 0, 197 ] ] } ]
[ { "id": "split_0_train_87_entity", "type": "progene_text", "text": [ "Tec" ], "offsets": [ [ 42, 45 ] ], "normalized": [] }, { "id": "split_0_train_88_entity", "type": "progene_text", "text": [ "kinase" ], "offsets": [ [ 46, 52 ] ], "normalized": [] }, { "id": "split_0_train_89_entity", "type": "progene_text", "text": [ "serine / threonine kinase" ], "offsets": [ [ 103, 128 ] ], "normalized": [] }, { "id": "split_0_train_90_entity", "type": "progene_text", "text": [ "Akt" ], "offsets": [ [ 129, 132 ] ], "normalized": [] }, { "id": "split_0_train_91_entity", "type": "progene_text", "text": [ "BCR" ], "offsets": [ [ 164, 167 ] ], "normalized": [] }, { "id": "split_0_train_92_entity", "type": "progene_text", "text": [ "FcgammaRIIb1" ], "offsets": [ [ 172, 184 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_57
split_0_train_57
[ { "id": "split_0_train_57_passage", "type": "progene_text", "text": [ "The association of PI3K with SHIP may serve to activate PI3K and to regulate downstream events such as B cell activation - induced apoptosis ." ], "offsets": [ [ 0, 142 ] ] } ]
[ { "id": "split_0_train_93_entity", "type": "progene_text", "text": [ "PI3K" ], "offsets": [ [ 19, 23 ] ], "normalized": [] }, { "id": "split_0_train_94_entity", "type": "progene_text", "text": [ "SHIP" ], "offsets": [ [ 29, 33 ] ], "normalized": [] }, { "id": "split_0_train_95_entity", "type": "progene_text", "text": [ "PI3K" ], "offsets": [ [ 56, 60 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_58
split_0_train_58
[ { "id": "split_0_train_58_passage", "type": "progene_text", "text": [ "Non-LTR retrotransposons ( LINEs ) as ubiquitous components of plant genomes ." ], "offsets": [ [ 0, 78 ] ] } ]
[]
[]
[]
[]
split_0_train_59
split_0_train_59
[ { "id": "split_0_train_59_passage", "type": "progene_text", "text": [ "During the course of work aimed at isolating a rice gene from Oryza australiensis by PCR , the oligonucleotide primers used were found to generate a fragment that showed sequence homology to the endonuclease ( EN ) region of the maize non - LTR retrotransposon ( LINE ) Cin4 ." ], "offsets": [ [ 0, 276 ] ] } ]
[ { "id": "split_0_train_96_entity", "type": "progene_text", "text": [ "endonuclease" ], "offsets": [ [ 195, 207 ] ], "normalized": [] }, { "id": "split_0_train_97_entity", "type": "progene_text", "text": [ "EN" ], "offsets": [ [ 210, 212 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_60
split_0_train_60
[ { "id": "split_0_train_60_passage", "type": "progene_text", "text": [ "We carried out further PCRs using oligonucleotide primers that hybridized to these sequences , and found that they amplified several fragments , each with homology to the EN regions , from Oryza sativa cv. Nipponbare as well as O. australiensis ." ], "offsets": [ [ 0, 246 ] ] } ]
[ { "id": "split_0_train_98_entity", "type": "progene_text", "text": [ "EN" ], "offsets": [ [ 171, 173 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_61
split_0_train_61
[ { "id": "split_0_train_61_passage", "type": "progene_text", "text": [ "We mapped the approximate locations of two rice LINE homologues by screening clones in a YAC library made from a rice ( O. sativa ) genome , and found that each homologue was present in a low copy number apparently at nonspecific regions on rice chromosomes ." ], "offsets": [ [ 0, 259 ] ] } ]
[]
[]
[]
[]
split_0_train_62
split_0_train_62
[ { "id": "split_0_train_62_passage", "type": "progene_text", "text": [ "We then carried out PCR using degenerate oligonucleotide primers which hybridized to the rice LINE homologues and Cin4 to ascertain whether LINE homologues are present in a variety of members of the plant kingdom , including angiosperms , gymnosperms , bracken , horsetail and liverwort ." ], "offsets": [ [ 0, 288 ] ] } ]
[]
[]
[]
[]
split_0_train_63
split_0_train_63
[ { "id": "split_0_train_63_passage", "type": "progene_text", "text": [ "Cloning and nucleotide sequencing revealed that 53 clones obtained from 27 out of 33 plant species contained LINE homologues ." ], "offsets": [ [ 0, 126 ] ] } ]
[]
[]
[]
[]
split_0_train_64
split_0_train_64
[ { "id": "split_0_train_64_passage", "type": "progene_text", "text": [ "In addition to these homologues , we identified four homologues with EN regions in the Arabidopsis thaliana genome by a computer search of databases ." ], "offsets": [ [ 0, 150 ] ] } ]
[ { "id": "split_0_train_99_entity", "type": "progene_text", "text": [ "EN" ], "offsets": [ [ 69, 71 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_65
split_0_train_65
[ { "id": "split_0_train_65_passage", "type": "progene_text", "text": [ "The nucleotide sequences of almost all the LINE homologues were greatly diverged , but the derived amino acid sequences were well conserved , and all contained glutamic acid and tyrosine residues at almost the same relative positions as in the the active site regions of AP ( apurinic / apyrimidinic ) - endonucleases ." ], "offsets": [ [ 0, 319 ] ] } ]
[ { "id": "split_0_train_100_entity", "type": "progene_text", "text": [ "AP ( apurinic / apyrimidinic ) - endonucleases" ], "offsets": [ [ 271, 317 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_66
split_0_train_66
[ { "id": "split_0_train_66_passage", "type": "progene_text", "text": [ "The EN regions in the LINE homologues from closely related plant species show a closer phylogenetic relationship , indicating that sequence divergence during vertical transmission has been a major influence upon the evolution of plant LINEs ." ], "offsets": [ [ 0, 242 ] ] } ]
[ { "id": "split_0_train_101_entity", "type": "progene_text", "text": [ "EN" ], "offsets": [ [ 4, 6 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_67
split_0_train_67
[ { "id": "split_0_train_67_passage", "type": "progene_text", "text": [ "[ The effect of NO - like relaxing factor on vascular reactivity in tourniquet shock rat ]" ], "offsets": [ [ 0, 90 ] ] } ]
[]
[]
[]
[]
split_0_train_68
split_0_train_68
[ { "id": "split_0_train_68_passage", "type": "progene_text", "text": [ "This work was done on rat tourniquet shock ( ToS ) model ." ], "offsets": [ [ 0, 58 ] ] } ]
[]
[]
[]
[]
split_0_train_69
split_0_train_69
[ { "id": "split_0_train_69_passage", "type": "progene_text", "text": [ "It was found that reactivity of isolated perfused aortic ring to noradrenaline decreased , while cGMP content of the aortic tissue increased ." ], "offsets": [ [ 0, 142 ] ] } ]
[]
[]
[]
[]
split_0_train_70
split_0_train_70
[ { "id": "split_0_train_70_passage", "type": "progene_text", "text": [ "These changes could be potentiated by perfusion with L-arginine ( NO-precursor ) ." ], "offsets": [ [ 0, 82 ] ] } ]
[]
[]
[]
[]
split_0_train_71
split_0_train_71
[ { "id": "split_0_train_71_passage", "type": "progene_text", "text": [ "On the other side , when the aortic ring was perfused with L-NNA ( NO-synthesis inhibitor ) or methylene blue ( soluble cGMPase inhibitor ) , the changes could be attenuated ." ], "offsets": [ [ 0, 175 ] ] } ]
[ { "id": "split_0_train_102_entity", "type": "progene_text", "text": [ "cGMPase" ], "offsets": [ [ 120, 127 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_72
split_0_train_72
[ { "id": "split_0_train_72_passage", "type": "progene_text", "text": [ "The effect of these drugs are independent of the presence of vascular endothelium ." ], "offsets": [ [ 0, 83 ] ] } ]
[]
[]
[]
[]
split_0_train_73
split_0_train_73
[ { "id": "split_0_train_73_passage", "type": "progene_text", "text": [ "The results suggest that non - endothelium - derived NO - like relaxing factor may be one of the factors causing low vascular reactivity of the ToS animals ." ], "offsets": [ [ 0, 157 ] ] } ]
[]
[]
[]
[]
split_0_train_74
split_0_train_74
[ { "id": "split_0_train_74_passage", "type": "progene_text", "text": [ "Systematic identification , classification , and characterization of the open reading frames which encode novel helicase - related proteins in Saccharomyces cerevisiae by gene disruption and Northern analysis ." ], "offsets": [ [ 0, 210 ] ] } ]
[ { "id": "split_0_train_103_entity", "type": "progene_text", "text": [ "helicase" ], "offsets": [ [ 112, 120 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_75
split_0_train_75
[ { "id": "split_0_train_75_passage", "type": "progene_text", "text": [ "Helicase - related proteins play important roles in various cellular processes incuding DNA replication , DNA repair , RNA processing and so on ." ], "offsets": [ [ 0, 145 ] ] } ]
[ { "id": "split_0_train_104_entity", "type": "progene_text", "text": [ "Helicase" ], "offsets": [ [ 0, 8 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_76
split_0_train_76
[ { "id": "split_0_train_76_passage", "type": "progene_text", "text": [ "It has been well known that the amino acid sequences of these proteins contain several conserved motifs , and that the open reading frames ( ORFs ) which encode helicase - related proteins make up several gene families ." ], "offsets": [ [ 0, 220 ] ] } ]
[ { "id": "split_0_train_105_entity", "type": "progene_text", "text": [ "helicase" ], "offsets": [ [ 161, 169 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_77
split_0_train_77
[ { "id": "split_0_train_77_passage", "type": "progene_text", "text": [ "In this study , we have identified 134 ORFs that encode helicase - like proteins in the Saccharomyces genome , based on similarity with the ORFs of authentic helicase and helicase - related proteins ." ], "offsets": [ [ 0, 200 ] ] } ]
[ { "id": "split_0_train_106_entity", "type": "progene_text", "text": [ "helicase" ], "offsets": [ [ 56, 64 ] ], "normalized": [] }, { "id": "split_0_train_107_entity", "type": "progene_text", "text": [ "helicase" ], "offsets": [ [ 158, 166 ] ], "normalized": [] }, { "id": "split_0_train_108_entity", "type": "progene_text", "text": [ "helicase" ], "offsets": [ [ 171, 179 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_78
split_0_train_78
[ { "id": "split_0_train_78_passage", "type": "progene_text", "text": [ "Multiple alignment of the ORF sequences resulted in the 134 ORFs being classified to 11 clusters ." ], "offsets": [ [ 0, 98 ] ] } ]
[]
[]
[]
[]
split_0_train_79
split_0_train_79
[ { "id": "split_0_train_79_passage", "type": "progene_text", "text": [ "Seven out of 21 previously uncharacterized ORFs ( YDL031w , YDL070w , YDL084w , YGL150c , YKL078w , YLR276c , and YMR128w ) were identified by systematic gene disruption , to be essential for vegetative growth ." ], "offsets": [ [ 0, 211 ] ] } ]
[ { "id": "split_0_train_109_entity", "type": "progene_text", "text": [ "YDL031w" ], "offsets": [ [ 50, 57 ] ], "normalized": [] }, { "id": "split_0_train_110_entity", "type": "progene_text", "text": [ "YDL070w" ], "offsets": [ [ 60, 67 ] ], "normalized": [] }, { "id": "split_0_train_111_entity", "type": "progene_text", "text": [ "YDL084w" ], "offsets": [ [ 70, 77 ] ], "normalized": [] }, { "id": "split_0_train_112_entity", "type": "progene_text", "text": [ "YGL150c" ], "offsets": [ [ 80, 87 ] ], "normalized": [] }, { "id": "split_0_train_113_entity", "type": "progene_text", "text": [ "YKL078w" ], "offsets": [ [ 90, 97 ] ], "normalized": [] }, { "id": "split_0_train_114_entity", "type": "progene_text", "text": [ "YLR276c" ], "offsets": [ [ 100, 107 ] ], "normalized": [] }, { "id": "split_0_train_115_entity", "type": "progene_text", "text": [ "YMR128w" ], "offsets": [ [ 114, 121 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_80
split_0_train_80
[ { "id": "split_0_train_80_passage", "type": "progene_text", "text": [ "Three ( YDR332w , YGL064c , and YOL095c ) out of the remaining 14 dispensable ORFs exhibited the slow - growth phenotype at 30 degrees C and 37 degrees C ." ], "offsets": [ [ 0, 155 ] ] } ]
[ { "id": "split_0_train_116_entity", "type": "progene_text", "text": [ "YDR332w" ], "offsets": [ [ 8, 15 ] ], "normalized": [] }, { "id": "split_0_train_117_entity", "type": "progene_text", "text": [ "YGL064c" ], "offsets": [ [ 18, 25 ] ], "normalized": [] }, { "id": "split_0_train_118_entity", "type": "progene_text", "text": [ "YOL095c" ], "offsets": [ [ 32, 39 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_81
split_0_train_81
[ { "id": "split_0_train_81_passage", "type": "progene_text", "text": [ "Furthermore , the expression profiles of transcripts from 43 ORFs were examined under seven different growth conditions by Northern analysis and reverse transcription - polymerase chain reaction , indicating that all of the 43 tested ORFs were transcribed ." ], "offsets": [ [ 0, 257 ] ] } ]
[]
[]
[]
[]
split_0_train_82
split_0_train_82
[ { "id": "split_0_train_82_passage", "type": "progene_text", "text": [ "Interestingly , we found that the level of transcript from 34 helicase - like genes was markedly increased by heat shock ." ], "offsets": [ [ 0, 122 ] ] } ]
[ { "id": "split_0_train_119_entity", "type": "progene_text", "text": [ "helicase" ], "offsets": [ [ 62, 70 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_83
split_0_train_83
[ { "id": "split_0_train_83_passage", "type": "progene_text", "text": [ "This suggests that helicase - like genes may be involved in the biosynthesis of nucleic acids and proteins , and that the genes can be transcriptionally activated by heat shock to compensate for the repressed synthesis of mRNA and protein ." ], "offsets": [ [ 0, 240 ] ] } ]
[ { "id": "split_0_train_120_entity", "type": "progene_text", "text": [ "helicase" ], "offsets": [ [ 19, 27 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_84
split_0_train_84
[ { "id": "split_0_train_84_passage", "type": "progene_text", "text": [ "A novel ubiquitin - specific protease , UBP43 , cloned from leukemia fusion protein AML1 - ETO - expressing mice , functions in hematopoietic cell differentiation ." ], "offsets": [ [ 0, 164 ] ] } ]
[ { "id": "split_0_train_121_entity", "type": "progene_text", "text": [ "ubiquitin" ], "offsets": [ [ 8, 17 ] ], "normalized": [] }, { "id": "split_0_train_122_entity", "type": "progene_text", "text": [ "protease" ], "offsets": [ [ 29, 37 ] ], "normalized": [] }, { "id": "split_0_train_123_entity", "type": "progene_text", "text": [ "UBP43" ], "offsets": [ [ 40, 45 ] ], "normalized": [] }, { "id": "split_0_train_124_entity", "type": "progene_text", "text": [ "AML1" ], "offsets": [ [ 84, 88 ] ], "normalized": [] }, { "id": "split_0_train_125_entity", "type": "progene_text", "text": [ "ETO" ], "offsets": [ [ 91, 94 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_85
split_0_train_85
[ { "id": "split_0_train_85_passage", "type": "progene_text", "text": [ "Using PCR - coupled subtractive screening - representational difference analysis , we have cloned a novel gene from AML1 - ETO knockin mice ." ], "offsets": [ [ 0, 141 ] ] } ]
[ { "id": "split_0_train_126_entity", "type": "progene_text", "text": [ "AML1" ], "offsets": [ [ 116, 120 ] ], "normalized": [] }, { "id": "split_0_train_127_entity", "type": "progene_text", "text": [ "ETO" ], "offsets": [ [ 123, 126 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_86
split_0_train_86
[ { "id": "split_0_train_86_passage", "type": "progene_text", "text": [ "This gene is highly expressed in the yolk sac and fetal liver of the knockin mice ." ], "offsets": [ [ 0, 83 ] ] } ]
[]
[]
[]
[]
split_0_train_87
split_0_train_87
[ { "id": "split_0_train_87_passage", "type": "progene_text", "text": [ "Nucleotide sequence analysis indicates that its cDNA contains an 1,107-bp open reading frame encoding a 368 - amino - acid polypeptide ." ], "offsets": [ [ 0, 136 ] ] } ]
[]
[]
[]
[]
split_0_train_88
split_0_train_88
[ { "id": "split_0_train_88_passage", "type": "progene_text", "text": [ "Further protein sequence and protein translation analysis shows that it belongs to a family of ubiquitin - specific proteases ( UBP ) , and its molecular mass is 43 kDa ." ], "offsets": [ [ 0, 170 ] ] } ]
[ { "id": "split_0_train_128_entity", "type": "progene_text", "text": [ "family of ubiquitin - specific proteases" ], "offsets": [ [ 85, 125 ] ], "normalized": [] }, { "id": "split_0_train_129_entity", "type": "progene_text", "text": [ "UBP" ], "offsets": [ [ 128, 131 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_89
split_0_train_89
[ { "id": "split_0_train_89_passage", "type": "progene_text", "text": [ "Therefore , we have named this gene UBP43 ." ], "offsets": [ [ 0, 43 ] ] } ]
[ { "id": "split_0_train_130_entity", "type": "progene_text", "text": [ "UBP43" ], "offsets": [ [ 36, 41 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_90
split_0_train_90
[ { "id": "split_0_train_90_passage", "type": "progene_text", "text": [ "Like other ubiquitin proteases , the UBP43 protein has deubiquitinating enzyme activity ." ], "offsets": [ [ 0, 89 ] ] } ]
[ { "id": "split_0_train_131_entity", "type": "progene_text", "text": [ "ubiquitin proteases" ], "offsets": [ [ 11, 30 ] ], "normalized": [] }, { "id": "split_0_train_132_entity", "type": "progene_text", "text": [ "UBP43" ], "offsets": [ [ 37, 42 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_91
split_0_train_91
[ { "id": "split_0_train_91_passage", "type": "progene_text", "text": [ "Protein ubiquitination has been implicated in many important cellular events ." ], "offsets": [ [ 0, 78 ] ] } ]
[]
[]
[]
[]
split_0_train_92
split_0_train_92
[ { "id": "split_0_train_92_passage", "type": "progene_text", "text": [ "In wild - type adult mice , UBP43 is highly expressed in the thymus and in peritoneal macrophages ." ], "offsets": [ [ 0, 99 ] ] } ]
[ { "id": "split_0_train_133_entity", "type": "progene_text", "text": [ "UBP43" ], "offsets": [ [ 28, 33 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_93
split_0_train_93
[ { "id": "split_0_train_93_passage", "type": "progene_text", "text": [ "Among nine different murine hematopoietic cell lines analyzed , UBP43 expression is detectable only in cell lines related to the monocytic lineage ." ], "offsets": [ [ 0, 148 ] ] } ]
[ { "id": "split_0_train_134_entity", "type": "progene_text", "text": [ "UBP43" ], "offsets": [ [ 64, 69 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_94
split_0_train_94
[ { "id": "split_0_train_94_passage", "type": "progene_text", "text": [ "Furthermore , its expression is regulated during cytokine - induced monocytic cell differentiation ." ], "offsets": [ [ 0, 100 ] ] } ]
[ { "id": "split_0_train_135_entity", "type": "progene_text", "text": [ "cytokine" ], "offsets": [ [ 49, 57 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_95
split_0_train_95
[ { "id": "split_0_train_95_passage", "type": "progene_text", "text": [ "We have investigated its function in the hematopoietic myeloid cell line M1 ." ], "offsets": [ [ 0, 77 ] ] } ]
[]
[]
[]
[]
split_0_train_96
split_0_train_96
[ { "id": "split_0_train_96_passage", "type": "progene_text", "text": [ "UBP43 was introduced into M1 cells by retroviral gene transfer , and several high - expressing UBP43 clones were obtained for further study ." ], "offsets": [ [ 0, 141 ] ] } ]
[ { "id": "split_0_train_136_entity", "type": "progene_text", "text": [ "UBP43" ], "offsets": [ [ 0, 5 ] ], "normalized": [] }, { "id": "split_0_train_137_entity", "type": "progene_text", "text": [ "UBP43" ], "offsets": [ [ 95, 100 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_97
split_0_train_97
[ { "id": "split_0_train_97_passage", "type": "progene_text", "text": [ "Morphologic and cell surface marker examination of UBP43 / M1 cells reveals that overexpression of UBP43 blocks cytokine - induced terminal differentiation of monocytic cells ." ], "offsets": [ [ 0, 176 ] ] } ]
[ { "id": "split_0_train_138_entity", "type": "progene_text", "text": [ "UBP43" ], "offsets": [ [ 51, 56 ] ], "normalized": [] }, { "id": "split_0_train_139_entity", "type": "progene_text", "text": [ "UBP43" ], "offsets": [ [ 99, 104 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_98
split_0_train_98
[ { "id": "split_0_train_98_passage", "type": "progene_text", "text": [ "These data suggest that UBP43 plays an important role in hematopoiesis by modulating either the ubiquitin - dependent proteolytic pathway or the ubiquitination state of another regulatory factor(s) during myeloid cell differentiation ." ], "offsets": [ [ 0, 235 ] ] } ]
[ { "id": "split_0_train_140_entity", "type": "progene_text", "text": [ "UBP43" ], "offsets": [ [ 24, 29 ] ], "normalized": [] }, { "id": "split_0_train_141_entity", "type": "progene_text", "text": [ "ubiquitin" ], "offsets": [ [ 96, 105 ] ], "normalized": [] } ]
[]
[]
[]
split_0_train_99
split_0_train_99
[ { "id": "split_0_train_99_passage", "type": "progene_text", "text": [ "Reduced inotropic support after aprotinin therapy during pediatric cardiac operations ." ], "offsets": [ [ 0, 87 ] ] } ]
[]
[]
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Dataset Card for ProGene

The Protein/Gene corpus was developed at the JULIE Lab Jena under supervision of Prof. Udo Hahn. The executing scientist was Dr. Joachim Wermter. The main annotator was Dr. Rico Pusch who is an expert in biology. The corpus was developed in the context of the StemNet project (http://www.stemnet.de/).

Citation Information

@inproceedings{faessler-etal-2020-progene,
    title = "{P}ro{G}ene - A Large-scale, High-Quality Protein-Gene Annotated Benchmark Corpus",
    author = "Faessler, Erik  and
      Modersohn, Luise  and
      Lohr, Christina  and
      Hahn, Udo",
    booktitle = "Proceedings of the 12th Language Resources and Evaluation Conference",
    month = may,
    year = "2020",
    address = "Marseille, France",
    publisher = "European Language Resources Association",
    url = "https://aclanthology.org/2020.lrec-1.564",
    pages = "4585--4596",
    abstract = "Genes and proteins constitute the fundamental entities of molecular genetics. We here introduce ProGene (formerly called FSU-PRGE), a corpus that reflects our efforts to cope with this important class of named entities within the framework of a long-lasting large-scale annotation campaign at the Jena University Language {\&} Information Engineering (JULIE) Lab. We assembled the entire corpus from 11 subcorpora covering various biological domains to achieve an overall subdomain-independent corpus. It consists of 3,308 MEDLINE abstracts with over 36k sentences and more than 960k tokens annotated with nearly 60k named entity mentions. Two annotators strove for carefully assigning entity mentions to classes of genes/proteins as well as families/groups, complexes, variants and enumerations of those where genes and proteins are represented by a single class. The main purpose of the corpus is to provide a large body of consistent and reliable annotations for supervised training and evaluation of machine learning algorithms in this relevant domain. Furthermore, we provide an evaluation of two state-of-the-art baseline systems {---} BioBert and flair {---} on the ProGene corpus. We make the evaluation datasets and the trained models available to encourage comparable evaluations of new methods in the future.",
    language = "English",
    ISBN = "979-10-95546-34-4",
}
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