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E016/0004 | <image> Select the two depth ranges with the largest difference between the two data in the figure. | [
"(A) 0-100m",
"(B) 100-200m",
"(C) 200-300m",
"(D) 300-400m"
]
| ['C', 'D'] | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/E016_cmip6_cmp_Gulf_of_Mexico_INM-CM5-0_14c900ad5919bba556fcb021f76bc50d.png"
]
| mcq | earth | en |
E016/0005 | <image> Select the two depth ranges with the largest difference between the two data in the figure. | [
"(A) 0-100m",
"(B) 100-200m",
"(C) 200-300m",
"(D) 300-400m"
]
| ['C', 'D'] | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/E016_cmip6_cmp_Gulfstream_INM-CM5-0_61b14b24c40fd281442f937f721869d5.png"
]
| mcq | earth | en |
E016/0006 | <image> Select the two depth ranges with the largest difference between the two data in the figure. | [
"(A) 0-100m",
"(B) 100-200m",
"(C) 200-300m",
"(D) 300-400m"
]
| ['B', 'C'] | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/E016_cmip6_cmp_Peru-Chile_Coast_INM-CM5-0_6135dd09e9b0052c1f4c58de00cf8dad.png"
]
| mcq | earth | en |
E016/0007 | <image> Select the two depth ranges with the largest difference between the two data in the figure. | [
"(A) 0-100m",
"(B) 100-200m",
"(C) 200-300m",
"(D) 300-400m"
]
| ['A', 'B'] | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/E016_cmip6_cmp_Sargasso_Sea_INM-CM5-0_4edc89c28b77c1ebb3bc1126cfa9ab4b.png"
]
| mcq | earth | en |
E016/0008 | <image> Select the two depth ranges with the largest difference between the two data in the figure. | [
"(A) 0-100m",
"(B) 100-200m",
"(C) 200-300m",
"(D) 300-400m"
]
| ['C', 'D'] | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/E016_cmip6_cmp_South_Pacific_Subtropical_BCC-CSM2-MR_9cf12b76c678d3ee5c5e221cba065ae1.png"
]
| mcq | earth | en |
E016/0009 | <image> Select the two depth ranges with the largest difference between the two data in the figure. | [
"(A) 0-100m",
"(B) 100-200m",
"(C) 200-300m",
"(D) 300-400m"
]
| ['A', 'B'] | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/E016_cmip6_cmp_Western_Pacific_Warm_Pool_CAS-ESM2-0_62bb24309888e60b52d5277c4cd13ec7.png"
]
| mcq | earth | en |
E017/0000 | <image> The following figure shows the global surface temperature anomaly. Please select the two approximate areas with the hottest and coldest temperature anomalies respectively. | [
"North Central Eurasia",
"Qinghai-Tibet Plateau",
"East Asia",
"Northern North America"
]
| ['A', 'D'] | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/E017_era5_t2m_ano_2005-01_c3580aa35ac1fad35caf7ac23c5f46a5.png"
]
| mcq | earth | en |
E017/0001 | <image> The following figure shows the global surface temperature anomaly. Please select the two approximate areas with the hottest and coldest temperature anomalies respectively. | [
"Central Asia",
"Europe",
"Northwest North America",
"Greenland"
]
| ['B', 'D'] | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/E017_era5_t2m_ano_2005-03_0951ac5ff6bbb39d8d4d433e75311b43.png"
]
| mcq | earth | en |
E017/0002 | <image> The following figure shows the global surface temperature anomaly. Please select the two approximate areas with the hottest and coldest temperature anomalies respectively. | [
"Northeast Asia",
"Central Asia",
"Northwest North America",
"North Africa"
]
| ['A', 'C'] | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/E017_era5_t2m_ano_2006-11_122885effc4b931cfd8f888a30c11705.png"
]
| mcq | earth | en |
E017/0003 | <image> The following figure shows the global surface temperature anomaly. Please select the two approximate areas with the hottest and coldest temperature anomalies respectively. | [
"Northeastern North America",
"South North America",
"North Central Eurasia",
"North Africa"
]
| ['A', 'C'] | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/E017_era5_t2m_ano_2010-02_3951009f464d6ceeb234d9a4dd261106.png"
]
| mcq | earth | en |
E017/0004 | <image> The following figure shows the global surface temperature anomaly. Please select the two approximate areas with the hottest and coldest temperature anomalies respectively. | [
"Northwest North America",
"Northeast Asia",
"Central Asia",
"Australia"
]
| ['A', 'B'] | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/E017_era5_t2m_ano_2013-10_ff49864182c7f4a6311cda6665c96635.png"
]
| mcq | earth | en |
E017/0005 | <image> The following figure shows the global surface temperature anomaly. Please select the two approximate areas with the hottest and coldest temperature anomalies respectively. | [
"Central Eurasia",
"North Africa",
"Qinghai-Tibet Plateau",
"Northeastern North America"
]
| ['A', 'B'] | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/E017_era5_t2m_ano_2016-11_14060e00317b197be57cdb64b3fdab1e.png"
]
| mcq | earth | en |
E017/0006 | <image> The following figure shows the global surface temperature anomaly. Please select the two approximate areas with the hottest and coldest temperature anomalies respectively. | [
"Australia",
"Northern Eurasia",
"Northwest North America",
"South North America"
]
| ['B', 'C'] | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/E017_era5_t2m_ano_2017-03_f00f4e368347ce953b6b900365ee8339.png"
]
| mcq | earth | en |
E017/0007 | <image> The following figure shows the global surface temperature anomaly. Please select the two approximate areas with the hottest and coldest temperature anomalies respectively. | [
"Bering Sea",
"Australia",
"Central Asia",
"Northern North America"
]
| ['A', 'D'] | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/E017_era5_t2m_ano_2018-09_f180550b3165fc8a1a3df1d5c43346b3.png"
]
| mcq | earth | en |
E017/0008 | <image> The following figure shows the global surface temperature anomaly. Please select the two approximate areas with the hottest and coldest temperature anomalies respectively. | [
"North Central Eurasia",
"Alaska",
"North Africa",
"Northern South America"
]
| ['A', 'B'] | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/E017_era5_t2m_ano_2020-02_1e9d714ba51c986db8b132174acf3f02.png"
]
| mcq | earth | en |
E017/0009 | <image> The following figure shows the global surface temperature anomaly. Please select the two approximate areas with the hottest and coldest temperature anomalies respectively. | [
"Australia",
"Europe",
"North Central Eurasia",
"North Central North America"
]
| ['C', 'D'] | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/E017_era5_t2m_ano_2020-04_dc39a4ebc57a499716fb70a89c78ea71.png"
]
| mcq | earth | en |
L009/0000 | From the molecular structure PDB image <image>, (remove hydrogen atoms), please answer number of ligand chains with integers | []
| 2 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L009_0000_36cc460084784c4d33633626296aba64.png"
]
| exact_match | life | en |
L009/0001 | From the molecular structure PDB image <image>, (remove hydrogen atoms), please answer the number of ligand chains with integers | []
| 2 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L009_0001_ea63daa71ac60dbda11b388d0f829676.png"
]
| exact_match | life | en |
L009/0002 | From the molecular structure PDB image <image>, (remove hydrogen atoms), please answer the number of ligand chains with integers | []
| 0 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L009_0002_e3475ae3472de5584f343b1657a7b157.png"
]
| exact_match | life | en |
L009/0003 | From the molecular structure PDB image <image>, (remove hydrogen atoms), please answer the number of ligand chains with integers | []
| 1 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L009_0003_ad635cce982c8d251b840b5af220d256.png"
]
| exact_match | life | en |
L009/0004 | From the molecular structure PDB image <image>, (remove hydrogen atoms), please answer the number of ligand chains with integers | []
| 2 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L009_0004_09de6dd140d462ab5f2de068a7f74112.png"
]
| exact_match | life | en |
L009/0005 | From the molecular structure PDB image <image>, (remove hydrogen atoms), please answer the number of ligand chains with integers | []
| 4 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L009_0005_5e57d2fbfcdf424fefc2f129982df092.png"
]
| exact_match | life | en |
L009/0006 | From the molecular structure PDB image <image>, (remove hydrogen atoms), please answer the number of ligand chains with integers | []
| 3 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L009_0006_1de6d9d3ab0be5b3b6620f9fe707b421.png"
]
| exact_match | life | en |
L009/0007 | From the molecular structure PDB image <image>, (remove hydrogen atoms), please answer the number of ligand chains with integers | []
| 6 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L009_0007_8cb6c9e8ee4d9713e144f68523a79928.png"
]
| exact_match | life | en |
L009/0008 | From the molecular structure PDB image <image>, (remove hydrogen atoms), please answer the number of ligand chains with integers | []
| 2 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L009_0008_6ee42cd57b2a75d7ce52e31cf3062f85.png"
]
| exact_match | life | en |
L009/0009 | From the molecular structure PDB image <image>, (remove hydrogen atoms), please answer the number of ligand chains with integers | []
| 4 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L009_0009_348940deb429e87fa79ba931e5c31b24.png"
]
| exact_match | life | en |
L009/0010 | From the molecular structure PDB image <image>, (remove hydrogen atoms), please answer the number of ligand chains with integers | []
| 4 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L009_0010_145336c471bb33a20444ab39e93de133.png"
]
| exact_match | life | en |
L009/0011 | From the molecular structure PDB image <image>, (remove hydrogen atoms), please answer the number of ligand chains with integers | []
| 1 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L009_0011_6972c92122d25cf10a374e95b807c49d.png"
]
| exact_match | life | en |
L020/0000 | You are a professional biologist, andy you are skilled at reading and analyzing RNA secondary structure pictures. Please generate a natural language description for the given RNA <image>, find the length, describe the internal loops and hairpin loops of the RNA and point out their start and terminate position. | []
| The RNA is comprised of 119 bases in total, which has two internal loops from position U21 to C26, position U53 to C57; from position A71 to A78 and from position G9 to C104, and it also has two hairpin loops from position U33 to C44 and from position G85 to A90 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L020_0000_79dd9fdecadac779abdd899a08d8debd.png"
]
| open_ended | life | en |
L020/0001 | You are a professional biologist, andy you are skilled at reading and analyzing RNA secondary structure pictures. Please generate a natural language description for the given RNA <image>, find the length, describe the internal loops and hairpin loops of the RNA and point out their start and terminate position. | []
| The RNA is comprised of 201 bases in total, which has five internal loops from position U20 to A22 and U106 to U107; position U27 to G28 and position U100 to G101; position G32 to C41; position C80 to C84; position U119 to C123 and position U143 to U147; and it also has three hairpin loops from position U67 to U70 and from position C131 to A135 and from position A181 to U185. | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L020_0001_8e986c3fc94964f6f64232ef02c29633.png"
]
| open_ended | life | en |
L020/0002 | You are a professional biologist, andy you are skilled at reading and analyzing RNA secondary structure pictures. Please generate a natural language description for the given RNA <image>, find the length, describe the internal loops and hairpin loops of the RNA and point out their start and terminate position. | []
| The RNA is comprised of 68 bases in total, which has one internal loop from position A28 to U29 and position A41 to U42; and it also has one hairpin loop from position U31 to U39. | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L020_0002_9f64195f9863edc9e44b7cbef4c5739e.png"
]
| open_ended | life | en |
L020/0003 | You are a professional biologist, andy you are skilled at reading and analyzing RNA secondary structure pictures. Please generate a natural language description for the given RNA <image>, find the length, describe the internal loops and hairpin loops of the RNA and point out their start and terminate position. | []
| The RNA is comprised of 115 bases in total, which has three internal loops from position G9 to A10 and position A46 to A47; position A15 to A17 and position A39 to C41; position G70 to U71 and position A79 to A80; and it also has three hairpin loops from position U24 to U32; from position G73 to A77 and from position T96 to C101. | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L020_0003_8c8da09d5507b687c5a29475a295e6f2.png"
]
| open_ended | life | en |
L020/0004 | You are a professional biologist, andy you are skilled at reading and analyzing RNA secondary structure pictures. Please generate a natural language description for the given RNA <image>, find the length, describe the internal loops and hairpin loops of the RNA and point out their start and terminate position. | []
| The RNA is comprised of 35 bases in total, which has one internal loop from position C5 to U9 and position U21 to G24, and it also has one hairpin loop from position G13 to A16. | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L020_0004_a3594b6a3929d1c63c6212bc7e505652.png"
]
| open_ended | life | en |
L020/0005 | You are a professional biologist, andy you are skilled at reading and analyzing RNA secondary structure pictures. Please generate a natural language description for the given RNA <image>, find the length, describe the internal loops and hairpin loops of the RNA and point out their start and terminate position. | []
| The RNA is comprised of 76 bases in total, which has four internal loops from position A5 to A21; position G25 to A29 and A52 to A55; position C32 to C33; position A64 to C70, and it also has one hairpin loop from position C36 to G46. | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L020_0005_b3bae017337288abeb96659c8751f828.png"
]
| open_ended | life | en |
L020/0006 | You are a professional biologist, andy you are skilled at reading and analyzing RNA secondary structure pictures. Please generate a natural language description for the given RNA <image>, find the length, describe the internal loops and hairpin loops of the RNA and point out their start and terminate position. | []
| The RNA is comprised of 60 bases in total, which has one internal loop from position G11 to U14 and position A46 to U48, and it also has one hairpin loop from position G22 to G38. | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L020_0006_091030876171b8e620548f2d16499785.png"
]
| open_ended | life | en |
L020/0007 | You are a professional biologist, andy you are skilled at reading and analyzing RNA secondary structure pictures. Please generate a natural language description for the given RNA <image>, find the length, describe the internal loops and hairpin loops of the RNA and point out their start and terminate position. | []
| The RNA is comprised of 72 bases in total, which has only a hairpin loop from position A7 to C66. | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L020_0007_e570e47962c4ce7d7470146387409531.png"
]
| open_ended | life | en |
L020/0008 | You are a professional biologist, andy you are skilled at reading and analyzing RNA secondary structure pictures. Please generate a natural language description for the given RNA <image>, find the length, describe the internal loops and hairpin loops of the RNA and point out their start and terminate position. | []
| The RNA is comprised of 70 bases in total, which has only a hairpin loop from position U5 to A64. | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L020_0008_2d399cec9b9ec97411fcfc112973e331.png"
]
| open_ended | life | en |
L020/0009 | You are a professional biologist, andy you are skilled at reading and analyzing RNA secondary structure pictures. Please generate a natural language description for the given RNA <image>, find the length, describe the internal loops and hairpin loops of the RNA and point out their start and terminate position. | []
| The RNA is comprised of 60 bases in total, which has two internal loops in position U8 and C50; position C19, and it also has one hairpin loop from position T24 to T35. | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L020_0009_cc0448b28f03713bef48eba3c6d4fc64.png"
]
| open_ended | life | en |
L019/0000 | From the molecular structure PDB image <image>, which is from ENZYMATIC MECHANISM OF CREATINE AMIDINOHYDROLASE AS DEDUCED FROM CRYSTAL STRUCTURES, please give description of this structure in one paragraph | []
| The molecular structure depicted in the PDB image represents creatine amidinohydrolase, a protein enzyme involved in the enzymatic mechanism of creatine metabolism. The structure is visualized using a ribbon diagram, where different colors represent distinct chains or subunits of the protein. In this case, two main subunits are visible: one colored green and the other orange. The green subunit appears to dominate the structure, forming a complex network of alpha-helices and beta-sheets that contribute to the overall tertiary structure. The orange subunit, while smaller, interacts closely with the green subunit, likely playing a critical role in the enzyme's active site or catalytic function. Key residues involved in substrate binding or catalysis may be highlighted in blue or red, indicating their importance in the enzymatic mechanism. The intricate folding and arrangement of these secondary structural elements suggest a highly conserved and optimized structure for its biological function, which involves hydrolyzing creatine to produce guanidinoacetic acid and ammonia. This detailed visualization provides insights into how the enzyme's three-dimensional architecture facilitates its enzymatic activity. | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L019_0000_36cc460084784c4d33633626296aba64.png"
]
| open_ended | life | en |
L019/0001 | From the molecular structure PDB image <image>, which is from Crystal structure of IsdH linker-NEAT3 bound to a nanobody (VHH), please give description of this structure in one paragraph | []
| The molecular structure depicted in the PDB image represents the crystal structure of IsdH linker-NEAT3 bound to a nanobody (VHH). The ribbon diagram illustrates two distinct protein components: one colored orange and the other green. The orange subunit, representing the nanobody (VHH), exhibits a compact, globular structure characteristic of single-domain antibodies. Its secondary structure is dominated by beta-sheets, which form the canonical immunoglobulin-like fold typical of nanobodies. The green subunit, corresponding to the IsdH linker-NEAT3 domain, displays a more extended and flexible conformation, with a combination of alpha-helices and beta-strands that contribute to its overall tertiary structure. The interaction between the two proteins is evident from their close proximity and complementary surfaces, suggesting a specific binding interface. A small purple sphere near the interface likely represents a ligand or cofactor involved in stabilizing the complex. This structural arrangement highlights the precise recognition and binding mechanism between the nanobody and the IsdH linker-NEAT3 domain, providing insights into how these molecules interact to mediate biological functions or serve as potential therapeutic targets. | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L019_0001_ea63daa71ac60dbda11b388d0f829676.png"
]
| open_ended | life | en |
L019/0002 | From the molecular structure PDB image <image>, which is from SH2 (SRC HOMOLOGY-2) DOMAIN OF HUMAN P56-LCK TYROSINE KINASE COMPLEXED WITH THE 11 RESIDUE PHOSPHOTYROSYL PEPTIDE EPQPYEEIPIYL, please give description of this structure in one paragraph | []
| The SH2 (SRC Homology 2) domain of human P56-LCK tyrosine kinase complexed with the phosphotyrosyl peptide EPQPYEEIPIYL plays a crucial role in signal transduction. This domain specifically binds to phosphorylated tyrosine residues, with the pTyr in the peptide fitting into a hydrophobic pocket of the SH2 domain, facilitating strong interactions. This binding is essential for the activation of P56-LCK, which is involved in T-cell receptor signaling and immune responses. Understanding this interaction can provide valuable insights for developing therapeutic targets in cancer and autoimmune diseases. | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L019_0002_e3475ae3472de5584f343b1657a7b157.png"
]
| open_ended | life | en |
L019/0003 | From the molecular structure PDB image <image>, which is from crystal structure of epigallocatechin binding with alpha-lactalbumin, please give description of this structure in one paragraph | []
| The provided image displays the crystal structure of alpha-lactalbumin in complex with epigallocatechin (EGC). The alpha-lactalbumin protein is depicted as a teal ribbon diagram, illustrating its folded secondary structural elements, including alpha-helices and beta-sheets, which create a specific three-dimensional conformation. Bound to a surface pocket or cleft of the alpha-lactalbumin is the smaller epigallocatechin molecule, shown in a ball-and-stick model where atoms are represented by colored spheres (typically grey or white for carbon, red for oxygen, and white for hydrogen). This structural representation highlights the interaction site where EGC binds to the protein, a crucial aspect for understanding the molecular recognition and potential functional modulation of alpha-lactalbumin by EGC. | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L019_0003_ad635cce982c8d251b840b5af220d256.png"
]
| open_ended | life | en |
L019/0004 | From the molecular structure PDB image <image>, which is from crystal structure of human cyclic GMP-AMP synthase in complex with 5-(4-fluorophenyl)-2-methylpyrazole-3-carboxylic acid, please give description of this structure in one paragraph | []
| this image displays the crystal structure of human cyclic GMP-AMP synthase (cGAS) in complex with 5-(4-fluorophenyl)-2-methylpyrazole-3-carboxylic acid. Human cGAS is a protein crucial for innate immunity, acting as a sensor for cytosolic DNA. The structure reveals a typical nucleotidyl transferase fold, characterized by an N-terminal α/β core and a C-terminal helix bundle. The N-terminal core contains centrally-twisted beta-sheets surrounded by alpha-helices. A notable feature is a zinc-finger domain, which is important for its DNA-binding and immune activation functions. The ligand, 5-(4-fluorophenyl)-2-methylpyrazole-3-carboxylic acid (a derivative of pyrazole-carboxylic acid), is shown bound to the protein, likely in or near the active site or a regulatory site, thereby influencing the enzyme's conformation and activity. The overall structure is predominantly composed of alpha-helices (coiled ribbons) and beta-sheets (flat arrows), with loop regions connecting them, all depicted in teal. The ligand molecule is shown in a ball-and-stick representation, with different colors indicating different atom types (e.g., grey for carbon, red for oxygen, blue for nitrogen, and light green for fluorine). Dashed lines suggest potential interactions, such as hydrogen bonds, between the ligand and the protein. This structural information is valuable for understanding how cGAS recognizes DNA and is activated, and for the development of therapeutics targeting cGAS-related pathways. | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L019_0004_09de6dd140d462ab5f2de068a7f74112.png"
]
| open_ended | life | en |
L019/0005 | From the molecular structure PDB image <image>, which is from Crystal Structure of human FABP4 in complex with 2-(5,6,7,8,9,10-hexahydrobenzo[8]annulen-3-yl)acetic acid, please give description of this structure in one paragraph | []
| The provided image displays the crystal structure of human Fatty Acid Binding Protein 4 (FABP4) in complex with the ligand 2-(5,6,7,8,9,10-hexahydrobenzoannulen-3-yl)acetic acid. The FABP4 protein, depicted in teal, adopts a characteristic β-barrel fold, composed of ten antiparallel β-strands that form a clam-shell like structure, creating an internal cavity. This cavity is where the ligand, shown in a ball-and-stick representation with grey/white carbons and red oxygens, is bound, indicating its role in sequestering and transporting fatty acids or related hydrophobic molecules. Short α-helical segments cap the ends of the β-barrel. Additionally, sulfate ions, likely from the crystallization buffer, are visible on the protein's surface, represented by yellow sulfur atoms and red oxygen atoms. | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L019_0005_5e57d2fbfcdf424fefc2f129982df092.png"
]
| open_ended | life | en |
L019/0006 | From the molecular structure PDB image <image>, which is from Structure of caprine serum albumin in P1 space group, please give description of this structure in one paragraph | []
| This image displays the crystal structure of caprine serum albumin in the P1 space group. The protein is a globular protein predominantly composed of α-helices (represented by the teal ribbon structures), which are tightly packed and interconnected by shorter loop regions, forming a complex three-dimensional conformation. Visible within or on the surface of the protein structure are small non-protein molecules (shown in ball-and-stick representation, where red likely indicates oxygen atoms and blue may represent nitrogen atoms), which could be bound ligands or solvent molecules trapped during crystallization, indicative of the protein's capacity to bind and transport various small molecules, a characteristic feature of serum albumins. | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L019_0006_1de6d9d3ab0be5b3b6620f9fe707b421.png"
]
| open_ended | life | en |
L019/0007 | From the molecular structure PDB image <image>, which is from Crystal structure of H. pylori isoleucyl-tRNA synthetase (HpIleRS) in complex with Ile-AMP, please give description of this structure in one paragraph | []
| This image shows the crystal structure of Helicobacter pylori isoleucyl-tRNA synthetase (HpIleRS) bound to its cognate ligand, isoleucyl-adenylate (Ile-AMP). The protein, depicted in teal, exhibits a complex, multi-domain architecture characterized by a combination of α-helical and β-sheet secondary structures, interconnected by various loop regions, forming an elongated overall shape. The Ile-AMP ligand, represented as a ball-and-stick model with atoms colored by element (e.g., red for oxygen, blue for nitrogen, orange for phosphorus), is nestled within a binding pocket, indicating the active site where the aminoacylation reaction, crucial for protein synthesis, takes place. This structure provides insight into the enzyme's mechanism for recognizing and activating isoleucine. | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L019_0007_8cb6c9e8ee4d9713e144f68523a79928.png"
]
| open_ended | life | en |
L019/0008 | From the molecular structure PDB image <image>, which is from SARS-Cov2 Main protease in complex with inhibitor CDD-1845, please give description of this structure in one paragraph | []
| This image displays the crystal structure of the SARS-CoV-2 Main protease (Mpro, also known as 3CLpro) in a dimeric form, with one monomer shown in orange and the other in teal. Each monomer exhibits a complex fold composed primarily of β-barrels and α-helices, forming a distinct active site cleft. Bound within the active site of each protomer is the inhibitor CDD-1845, depicted as a ball-and-stick model with atoms colored by element (e.g., blue for nitrogen, red for oxygen). The inhibitor's presence in this crucial enzymatic site highlights its potential to block the protease's activity, which is essential for viral replication. | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L019_0008_6ee42cd57b2a75d7ce52e31cf3062f85.png"
]
| open_ended | life | en |
L019/0009 | From the molecular structure PDB image <image>, which is from Crystal structure of Terrestrivirus Inositol pyrophosphatase kinase in complex with ADP and scyllo-IP6, please give description of this structure in one paragraph | []
| This image shows the crystal structure of Terrestrivirus Inositol pyrophosphatase kinase, depicted in teal, in complex with two ligands: ADP (adenosine diphosphate) and scyllo-IP6 (scyllo-inositol hexakisphosphate). The protein adopts a globular fold characterized by a mixture of α-helices and β-sheets, forming a binding cleft where the ligands are located. The scyllo-IP6 molecule, a highly phosphorylated inositol ring, is clearly visible with its multiple phosphate groups (orange phosphorus, red oxygen atoms) interacting with the protein. Adjacent to it, the ADP molecule is also bound, recognizable by its adenine base (ring structure with blue nitrogen atoms) and two phosphate groups. A small green sphere, likely representing a magnesium ion, is also present, often coordinating with nucleotide phosphates in kinase active sites. This complex structure illustrates the enzyme's active site with its substrates or products bound. | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L019_0009_348940deb429e87fa79ba931e5c31b24.png"
]
| open_ended | life | en |
L019/0010 | From the molecular structure PDB image <image>, which is from Crystal structure of Shewanella benthica Group 1 truncated hemoglobin Y34F C51S C71S variant (cyanomet), please give description of this structure in one paragraph | []
| This image displays the crystal structure of a variant (Y34F C51S C71S) of Shewanella benthica Group 1 truncated hemoglobin in its cyanomet form, arranged as a tetramer. The structure consists of four individual protein subunits, each depicted in a different color (teal, slate blue, magenta, and orange), and all adopting a similar globin fold predominantly composed of α-helices. Nestled within a hydrophobic pocket in each subunit is a heme group, shown as a ball-and-stick model, which is the site of oxygen binding in hemoglobins; in this cyanomet form, a cyanide ion is likely coordinated to the iron atom of the heme. The four subunits are packed together, suggesting a functional quaternary assembly for this truncated hemoglobin. | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L019_0010_145336c471bb33a20444ab39e93de133.png"
]
| open_ended | life | en |
L019/0011 | From the molecular structure PDB image <image>, which is from a peptide receptor complex structure, please give description of this structure in one paragraph | []
| This image illustrates a multi-component peptide receptor complex, showcasing distinct protein domains or subunits interacting with each other. The teal-colored portion, characterized by a bundle of transmembrane alpha-helices, represents the receptor itself, and notably, a small peptide or ligand molecule (shown in orange ball-and-stick representation) is bound within a pocket formed by these helices. Interacting with this receptor is an orange-colored protein or domain, which is also largely helical but incorporates some beta-sheet elements. Adjacent to and interacting with the orange domain is a slate-blue colored domain, which is predominantly composed of beta-sheets forming a beta-barrel or beta-sandwich structure, and also features some short magenta-colored alpha-helices on its periphery. Finally, a green-colored domain, also rich in beta-sheet structures, forms another part of the assembly, making contact with both the orange and slate-blue components. This intricate arrangement highlights the specific molecular interactions and overall architecture of a functional peptide receptor system. | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L019_0011_6972c92122d25cf10a374e95b807c49d.png"
]
| open_ended | life | en |
L005/0000 | From the compound's MS/MS spectrum <image>, determine the number of chlorine atoms based on isotope pattern and other compound information in the spectrum. | []
| 1 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L005_0000_fe87e31de1d5a00d7bd315c46ba760c3.png"
]
| exact_match | life | en |
L005/0001 | From the compound's MS/MS spectrum <image>, determine the number of sulfur atoms based on isotope pattern and other compound information in the spectrum. | []
| 1 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L005_0001_0b7370cee4f8ebdb216c1ad238ef27f4.png"
]
| exact_match | life | en |
L005/0002 | From the compound's MS/MS spectrum <image>, determine the number of chlorine atoms based on isotope pattern and other compound information in the spectrum. | []
| 0 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L005_0002_a7556f24d9065b2cddb3da8b9bd44429.png"
]
| exact_match | life | en |
L005/0003 | From the compound's MS/MS spectrum <image>, determine the number of chlorine atoms based on isotope pattern and other compound information in the spectrum. | []
| 0 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L005_0003_8096849a6ef437676acae87921f36c36.png"
]
| exact_match | life | en |
L005/0004 | From the compound's MS/MS spectrum <image>, determine the number of sulfur atoms based on isotope pattern and other compound information in the spectrum. | []
| 0 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L005_0004_43ddfaf9946f43815abf1ebe39525489.png"
]
| exact_match | life | en |
L005/0005 | From the compound's MS/MS spectrum <image>, determine the number of chlorine atoms based on isotope pattern and other compound information in the spectrum. | []
| 1 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L005_0005_150538d3068cbf5dfb60081638a789e3.png"
]
| exact_match | life | en |
L005/0006 | From the compound's MS/MS spectrum <image>, determine the number of chlorine atoms based on isotope pattern and other compound information in the spectrum. | []
| 2 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L005_0006_039ef4bf4b7525b9e2ced64bb382b8bc.png"
]
| exact_match | life | en |
L005/0007 | From the compound's MS/MS spectrum <image>, determine the number of nitrogen atoms based on isotope pattern and other compound information in the spectrum. | []
| 5 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L005_0007_ba1d358b7cb8d34dab5ae0f5c346ee60.png"
]
| exact_match | life | en |
L005/0008 | From the compound's MS/MS spectrum <image>, determine the number of chlorine atoms based on isotope pattern and other compound information in the spectrum. | []
| 1 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L005_0008_e2c2a20a2c75da61a167f0817cf8e3f2.png"
]
| exact_match | life | en |
L005/0009 | From the compound's MS/MS spectrum <image>, determine the number of fluorine atoms based on isotope pattern and other compound information in the spectrum. | []
| 1 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L005_0009_c21ceede4ba4c8b53827af312e972e24.png"
]
| exact_match | life | en |
L006/0000 | From the compound's MS/MS spectrum <image>, infer the elemental composition of the compound based on isotope patterns and other compound information present in the spectrum | []
| C, H, O, N, Cl | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L006_0000_fe87e31de1d5a00d7bd315c46ba760c3.png"
]
| exact_match | life | en |
L006/0001 | From the compound's MS/MS spectrum <image>, infer the elemental composition of the compound based on isotope patterns and other compound information present in the spectrum | []
| C, H, O, S | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L006_0001_0b7370cee4f8ebdb216c1ad238ef27f4.png"
]
| exact_match | life | en |
L006/0002 | From the compound's MS/MS spectrum <image>, infer the elemental composition of the compound based on isotope patterns and other compound information present in the spectrum | []
| C, H, O | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L006_0002_a7556f24d9065b2cddb3da8b9bd44429.png"
]
| exact_match | life | en |
L006/0003 | From the compound's MS/MS spectrum <image>, infer the elemental composition of the compound based on isotope patterns and other compound information present in the spectrum | []
| C, H, O | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L006_0003_8096849a6ef437676acae87921f36c36.png"
]
| exact_match | life | en |
L006/0004 | From the compound's MS/MS spectrum <image>, infer the elemental composition of the compound based on isotope patterns and other compound information present in the spectrum | []
| C, H, O | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L006_0004_43ddfaf9946f43815abf1ebe39525489.png"
]
| exact_match | life | en |
L006/0005 | From the compound's MS/MS spectrum <image>, infer the elemental composition of the compound based on isotope patterns and other compound information present in the spectrum | []
| C, H, N, Cl | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L006_0005_150538d3068cbf5dfb60081638a789e3.png"
]
| exact_match | life | en |
L006/0006 | From the compound's MS/MS spectrum <image>, infer the elemental composition of the compound based on isotope patterns and other compound information present in the spectrum | []
| C, H, O, N, Cl | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L006_0006_039ef4bf4b7525b9e2ced64bb382b8bc.png"
]
| exact_match | life | en |
L006/0007 | From the compound's MS/MS spectrum <image>, infer the elemental composition of the compound based on isotope patterns and other compound information present in the spectrum | []
| C, H, O, N | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L006_0007_ba1d358b7cb8d34dab5ae0f5c346ee60.png"
]
| exact_match | life | en |
L006/0008 | From the compound's MS/MS spectrum <image>, infer the elemental composition of the compound based on isotope patterns and other compound information present in the spectrum | []
| C, H, O, Cl | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L006_0008_e2c2a20a2c75da61a167f0817cf8e3f2.png"
]
| exact_match | life | en |
L006/0009 | From the compound's MS/MS spectrum <image>, infer the elemental composition of the compound based on isotope patterns and other compound information present in the spectrum | []
| C, H, O, N, F | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L006_0009_c21ceede4ba4c8b53827af312e972e24.png"
]
| exact_match | life | en |
L007/0000 | This is a multiple-choice question with only one correct answer. Based on given mass spectrum <image>, select the molecular structure that best matches it. | [
"(A) <image>",
"(B) <image>",
"(C) <image>",
"(D) <image>",
"(E) <image>",
"(F) <image>",
"(G) <image>"
]
| B | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0000_fe87e31de1d5a00d7bd315c46ba760c3.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0000_A_5402677babdb4c2e030b1aa85cf1ccce.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0000_B_56bfe241eb75d8ef031b4ce7d95cb037.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0000_C_e039f63cc8410d3f43e1df8440157366.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0000_D_36e0cef086eda65a1a179f8cafd6d2f6.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0000_E_36e0cef086eda65a1a179f8cafd6d2f6.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0000_F_b6b785ff18271d82a1fac6e703109d42.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0000_G_c0331e6a25250eed646c43f6e34024b0.png"
]
| mcq | life | en |
L007/0001 | This is a multiple-choice question with only one correct answer. Based on given mass spectrum <image>, select the molecular structure that best matches it. | [
"(A) <image>",
"(B) <image>",
"(C) <image>",
"(D) <image>",
"(E) <image>",
"(F) <image>",
"(G) <image>"
]
| C | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0001_0b7370cee4f8ebdb216c1ad238ef27f4.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0001_A_c0331e6a25250eed646c43f6e34024b0.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0001_B_56bfe241eb75d8ef031b4ce7d95cb037.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0001_C_9aa94eedce60de053990b75abc5faed3.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0001_D_5b57208b7b159c42dd3482e35e235804.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0001_E_36e0cef086eda65a1a179f8cafd6d2f6.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0001_F_b6b785ff18271d82a1fac6e703109d42.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0001_G_e039f63cc8410d3f43e1df8440157366.png"
]
| mcq | life | en |
L007/0002 | This is a multiple-choice question with only one correct answer. Based on given mass spectrum <image>, select the molecular structure that best matches it. | [
"(A) <image>",
"(B) <image>",
"(C) <image>",
"(D) <image>",
"(E) <image>",
"(F) <image>",
"(G) <image>"
]
| E | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0002_a7556f24d9065b2cddb3da8b9bd44429.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0002_A_9aa94eedce60de053990b75abc5faed3.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0002_B_3a6b0f8debef595bf8ccf01d639210e7.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0002_C_a07e8c5374d25e37831f5227e6ddb3b8.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0002_D_0dc4c6a712b75050cc56812e7f0dbb8b.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0002_E_5402677babdb4c2e030b1aa85cf1ccce.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0002_F_c877bab275b079b225590f7203516a68.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0002_G_b6b785ff18271d82a1fac6e703109d42.png"
]
| mcq | life | en |
L007/0003 | This is a multiple-choice question with only one correct answer. Based on given mass spectrum <image>, select the molecular structure that best matches it. | [
"(A) <image>",
"(B) <image>",
"(C) <image>",
"(D) <image>",
"(E) <image>",
"(F) <image>",
"(G) <image>"
]
| F | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0003_8096849a6ef437676acae87921f36c36.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0003_A_d975d5eeae796a56bdeebbb573b4f241.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0003_B_2a1037e3f1a3653feed7ebf1ff83447c.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0003_C_9aa94eedce60de053990b75abc5faed3.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0003_D_8cca5ce13e691b4928b476a3fe35ba72.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0003_E_56bfe241eb75d8ef031b4ce7d95cb037.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0003_F_1c662d666c9767d252820b8db917fd62.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0003_G_41feb09e24dddfe279c64282c7ea3ad8.png"
]
| mcq | life | en |
L007/0004 | This is a multiple-choice question with only one correct answer. Based on given mass spectrum <image>, select the molecular structure that best matches it. | [
"(A) <image>",
"(B) <image>",
"(C) <image>",
"(D) <image>",
"(E) <image>",
"(F) <image>",
"(G) <image>"
]
| A | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0004_43ddfaf9946f43815abf1ebe39525489.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0004_A_5b57208b7b159c42dd3482e35e235804.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0004_B_5402677babdb4c2e030b1aa85cf1ccce.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0004_C_41feb09e24dddfe279c64282c7ea3ad8.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0004_D_d975d5eeae796a56bdeebbb573b4f241.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0004_E_b6b785ff18271d82a1fac6e703109d42.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0004_F_c511ed097a8b5bb036b5bbdcf41c5175.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0004_G_a07e8c5374d25e37831f5227e6ddb3b8.png"
]
| mcq | life | en |
L007/0005 | This is a multiple-choice question with only one correct answer. Based on given mass spectrum <image>, select the molecular structure that best matches it. | [
"(A) <image>",
"(B) <image>",
"(C) <image>",
"(D) <image>",
"(E) <image>",
"(F) <image>",
"(G) <image>"
]
| B | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0005_150538d3068cbf5dfb60081638a789e3.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0005_A_c0331e6a25250eed646c43f6e34024b0.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0005_B_e039f63cc8410d3f43e1df8440157366.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0005_C_41feb09e24dddfe279c64282c7ea3ad8.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0005_D_0dc4c6a712b75050cc56812e7f0dbb8b.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0005_E_d975d5eeae796a56bdeebbb573b4f241.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0005_F_a07e8c5374d25e37831f5227e6ddb3b8.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0005_G_56bfe241eb75d8ef031b4ce7d95cb037.png"
]
| mcq | life | en |
L007/0006 | This is a multiple-choice question with only one correct answer. Based on given mass spectrum <image>, select the molecular structure that best matches it. | [
"(A) <image>",
"(B) <image>",
"(C) <image>",
"(D) <image>",
"(E) <image>",
"(F) <image>",
"(G) <image>"
]
| C | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0006_039ef4bf4b7525b9e2ced64bb382b8bc.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0006_A_05b7f34f9b541a3920e45f420ae38a5b.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0006_B_d975d5eeae796a56bdeebbb573b4f241.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0006_C_36e0cef086eda65a1a179f8cafd6d2f6.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0006_D_63572017906e8b320415da5509368fad.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0006_E_c877bab275b079b225590f7203516a68.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0006_F_c511ed097a8b5bb036b5bbdcf41c5175.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0006_G_a07e8c5374d25e37831f5227e6ddb3b8.png"
]
| mcq | life | en |
L007/0007 | This is a multiple-choice question with only one correct answer. Based on given mass spectrum <image>, select the molecular structure that best matches it. | [
"(A) <image>",
"(B) <image>",
"(C) <image>",
"(D) <image>",
"(E) <image>",
"(F) <image>",
"(G) <image>"
]
| G | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0007_ba1d358b7cb8d34dab5ae0f5c346ee60.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0007_A_05b7f34f9b541a3920e45f420ae38a5b.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0007_B_0dc4c6a712b75050cc56812e7f0dbb8b.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0007_C_c877bab275b079b225590f7203516a68.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0007_D_41feb09e24dddfe279c64282c7ea3ad8.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0007_E_56bfe241eb75d8ef031b4ce7d95cb037.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0007_F_e039f63cc8410d3f43e1df8440157366.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0007_G_63572017906e8b320415da5509368fad.png"
]
| mcq | life | en |
L007/0008 | This is a multiple-choice question with only one correct answer. Based on given mass spectrum <image>, select the molecular structure that best matches it. | [
"(A) <image>",
"(B) <image>",
"(C) <image>",
"(D) <image>",
"(E) <image>",
"(F) <image>",
"(G) <image>"
]
| A | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0008_e2c2a20a2c75da61a167f0817cf8e3f2.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0008_A_b6b785ff18271d82a1fac6e703109d42.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0008_B_c511ed097a8b5bb036b5bbdcf41c5175.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0008_C_05b7f34f9b541a3920e45f420ae38a5b.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0008_D_c0331e6a25250eed646c43f6e34024b0.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0008_E_63572017906e8b320415da5509368fad.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0008_F_d975d5eeae796a56bdeebbb573b4f241.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0008_G_c877bab275b079b225590f7203516a68.png"
]
| mcq | life | en |
L007/0009 | This is a multiple-choice question with only one correct answer. Based on given mass spectrum <image>, select the molecular structure that best matches it. | [
"(A) <image>",
"(B) <image>",
"(C) <image>",
"(D) <image>",
"(E) <image>",
"(F) <image>",
"(G) <image>"
]
| G | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0009_c21ceede4ba4c8b53827af312e972e24.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0009_A_c877bab275b079b225590f7203516a68.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0009_B_b6b785ff18271d82a1fac6e703109d42.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0009_C_c511ed097a8b5bb036b5bbdcf41c5175.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0009_D_e039f63cc8410d3f43e1df8440157366.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0009_E_0dc4c6a712b75050cc56812e7f0dbb8b.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0009_F_36e0cef086eda65a1a179f8cafd6d2f6.png",
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L007_0009_G_c0331e6a25250eed646c43f6e34024b0.png"
]
| mcq | life | en |
L014/0000 | Based on the RNA secondary structure diagram <image>, which of the following structures might the RNA contain? (Multiple choices) | [
"(A) stem",
"(B) Hairpin loop",
"(C) Interior loop",
"(D) bulge loop",
"(E) Multi-branched loop",
"(F) Pseudoknot"
]
| ['A', 'B', 'C', 'F'] | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L014_0000_160df97a486056f7868040c1fa6715fe.png"
]
| mcq | life | en |
L014/0001 | Based on the RNA secondary structure diagram <image>, which of the following structures might the RNA contain? (Multiple choices) | [
"(A) stem",
"(B) Hairpin loop",
"(C) Interior loop",
"(D) bulge loop",
"(E) Multi-branched loop",
"(F) Pseudoknot"
]
| ['A', 'B', 'E', 'F'] | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L014_0001_1fefe842779cecbdad46d823bb5c01b8.png"
]
| mcq | life | en |
L014/0002 | Based on the RNA secondary structure diagram <image>, which of the following structures might the RNA contain? (Multiple choices) | [
"(A) stem",
"(B) Hairpin loop",
"(C) Interior loop",
"(D) bulge loop",
"(E) Multi-branched loop",
"(F) Pseudoknot"
]
| ['A', 'B', 'C', 'D'] | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L014_0002_d1fabf619add4f41ef205897e9232736.png"
]
| mcq | life | en |
L014/0003 | Based on the RNA secondary structure diagram <image>, which of the following structures might the RNA contain? (Multiple choices) | [
"(A) stem",
"(B) Hairpin loop",
"(C) Interior loop",
"(D) bulge loop",
"(E) Multi-branched loop",
"(F) Pseudoknot"
]
| ['A', 'B', 'C', 'D'] | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L014_0003_791989b6398e60901c17fa86f861aea1.png"
]
| mcq | life | en |
L014/0004 | Based on the RNA secondary structure diagram <image>, which of the following structures might the RNA contain? (Multiple choices) | [
"(A) stem",
"(B) Hairpin loop",
"(C) Interior loop",
"(D) bulge loop",
"(E) Multi-branched loop",
"(F) Pseudoknot"
]
| ['A', 'B', 'C', 'D', 'E', 'F'] | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L014_0004_92393731237f2d6d66002074bc31a65d.png"
]
| mcq | life | en |
L014/0005 | Based on the RNA secondary structure diagram <image>, which of the following structures might the RNA contain? (Multiple choices) | [
"(A) stem",
"(B) Hairpin loop",
"(C) Interior loop",
"(D) bulge loop",
"(E) Multi-branched loop",
"(F) Pseudoknot"
]
| ['A', 'B', 'C', 'E', 'F'] | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L014_0005_636be9a4e82fb4ae714e3b75d2b9cdab.png"
]
| mcq | life | en |
L014/0006 | Based on the RNA secondary structure diagram <image>, which of the following structures might the RNA contain? (Multiple choices) | [
"(A) stem",
"(B) Hairpin loop",
"(C) Interior loop",
"(D) bulge loop",
"(E) Multi-branched loop",
"(F) Pseudoknot"
]
| ['A', 'B', 'F'] | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L014_0006_526df6e1a8302fabde97b701082e354b.png"
]
| mcq | life | en |
L014/0007 | Based on the RNA secondary structure diagram <image>, which of the following structures might the RNA contain? (Multiple choices) | [
"(A) stem",
"(B) Hairpin loop",
"(C) Interior loop",
"(D) bulge loop",
"(E) Multi-branched loop",
"(F) Pseudoknot"
]
| ['A', 'B', 'C', 'D', 'E', 'F'] | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L014_0007_8e0f85feec6977e4075544bdfa4c0af2.png"
]
| mcq | life | en |
L014/0008 | Based on the RNA secondary structure diagram <image>, which of the following structures might the RNA contain? (Multiple choices) | [
"(A) stem",
"(B) Hairpin loop",
"(C) Interior loop",
"(D) bulge loop",
"(E) Multi-branched loop",
"(F) Pseudoknot"
]
| ['A', 'B', 'C', 'D', 'E', 'F'] | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L014_0008_db7d72a6af426585e02ebff52a07dbf9.png"
]
| mcq | life | en |
L014/0009 | Based on the RNA secondary structure diagram <image>, which of the following structures might the RNA contain? (Multiple choices) | [
"(A) stem",
"(B) Hairpin loop",
"(C) Interior loop",
"(D) bulge loop",
"(E) Multi-branched loop",
"(F) Pseudoknot"
]
| ['A', 'B', 'C', 'D'] | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L014_0009_c307c032cf276201e7cdc1c281bf9209.png"
]
| mcq | life | en |
L015/0000 | Examine the given RNA secondary structure diagram <image>. How many stem regions are present in the structure? | []
| 6 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L015_0000_160df97a486056f7868040c1fa6715fe.png"
]
| exact_match | life | en |
L015/0001 | Examine the given RNA secondary structure diagram <image>. How many stem regions are present in the structure? | []
| 3 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L015_0001_1fefe842779cecbdad46d823bb5c01b8.png"
]
| exact_match | life | en |
L015/0002 | Examine the given RNA secondary structure diagram <image>. How many stem regions are present in the structure? | []
| 6 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L015_0002_d1fabf619add4f41ef205897e9232736.png"
]
| exact_match | life | en |
L015/0003 | Examine the given RNA secondary structure diagram <image>. How many stem regions are present in the structure? | []
| 5 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L015_0003_791989b6398e60901c17fa86f861aea1.png"
]
| exact_match | life | en |
L015/0004 | Examine the given RNA secondary structure diagram <image>. How many stem regions are present in the structure? | []
| 15 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L015_0004_92393731237f2d6d66002074bc31a65d.png"
]
| exact_match | life | en |
L015/0005 | Examine the given RNA secondary structure diagram <image>. How many stem regions are present in the structure? | []
| 4 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L015_0005_636be9a4e82fb4ae714e3b75d2b9cdab.png"
]
| exact_match | life | en |
L015/0006 | Examine the given RNA secondary structure diagram <image>. How many stem regions are present in the structure? | []
| 2 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L015_0006_526df6e1a8302fabde97b701082e354b.png"
]
| exact_match | life | en |
L015/0007 | Examine the given RNA secondary structure diagram <image>. How many stem regions are present in the structure? | []
| 10 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L015_0007_8e0f85feec6977e4075544bdfa4c0af2.png"
]
| exact_match | life | en |
L015/0008 | Examine the given RNA secondary structure diagram <image>. How many stem regions are present in the structure? | []
| 14 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L015_0008_db7d72a6af426585e02ebff52a07dbf9.png"
]
| exact_match | life | en |
L015/0009 | Examine the given RNA secondary structure diagram <image>. How many stem regions are present in the structure? | []
| 8 | [
"/fs-computility/ai4sData/earth-shared/SFE/sfe_dataset/v0/images/L015_0009_c307c032cf276201e7cdc1c281bf9209.png"
]
| exact_match | life | en |
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